Calculators Created by Prerana Bakli

University of Hawaiʻi at Mānoa (UH Manoa), Hawaii, USA
linkedin.com/in/prerana-bakli-960aa1179
835
Formulas Created
1597
Formulas Verified
305
Across Categories

List of Calculators by Prerana Bakli

Following is a combined list of all the calculators that have been created and verified by Prerana Bakli. Prerana Bakli has created 835 and verified 1597 calculators across 305 different categories till date.
Verified Number of Theoretical Plates given Resolution and Separation Factor
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Verified Number of Theoretical Plates given Retention Time and Half Width of Peak
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Verified Number of Theoretical Plates given Retention Time and Standard Deviation
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Verified Number of Theoretical Plates given Retention Time and Width of Peak
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Verified Separation Factor given Resolution and Number of Theoretical Plates
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4 More Number of Theoretical Plates Calculators
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Created Ratio Molar Heat Capacity given Compressibility
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Created Ratio of Molar Heat Capacity
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Created Ratio of Molar Heat Capacity given Degree of Freedom
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Created Ratio of Molar Heat Capacity given Molar Heat Capacity at Constant Pressure
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Created Ratio of Molar Heat Capacity given Molar Heat Capacity at Constant Volume
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Created Ratio of Molar Heat Capacity of Linear Molecule
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Created Ratio of Molar Heat Capacity of Non-Linear Molecule
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Created Reduced Temperature of Real Gas given 'a' using Redlich Kwong Equation
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Created Reduced Temperature of Real Gas given 'b' using Redlich Kwong Equation
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Created Reduced Temperature of Real Gas using Actual and Critical Temperature
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Created Reduced Temperature of Real Gas using Reduced Redlich Kwong Equation
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Created Reduced Temperature using Redlich Kwong Equation given of 'a' and 'b'
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Created Slope of Coexistence Curve given Pressure and Latent Heat
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Created Slope of Coexistence Curve given Specific Latent Heat
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Created Slope of Coexistence Curve of Water Vapor near Standard Temperature and Pressure
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Created Slope of Coexistence Curve using Enthalpy
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Created Slope of Coexistence Curve using Entropy
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Created Slope of Coexistence Curve using Latent Heat
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Created Acentric Factor
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Created Acentric Factor given Actual and Critical Saturation Vapor Pressure
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Verified Activitiy of Electrolyte given Concentration and Fugacity
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Verified Activity Coefficient given Ionic Activity
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Verified Activity Coefficient of Anodic Electrolyte of Concentration Cell without Transference
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Verified Activity Coefficient of Cathodic Electrolyte of Concentration Cell without Transference
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Verified Activity of Anodic Electrolyte of Concentration Cell with Transference
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Verified Activity of Anodic Electrolyte of Concentration Cell with Transference given Valencies
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Verified Activity of Anodic Electrolyte of Concentration Cell without Transference
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Verified Activity of Cathodic Electrolyte of Concentration Cell with Transference
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Verified Activity of Cathodic Electrolyte of Concentration Cell with Transference given Valencies
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Verified Activity of Cathodic Electrolyte of Concentration Cell without Transference
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1 More Activity of Electrolytes Calculators
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Created Actual Molar Volume of Real Gas given Wohl Parameter a, and Actual and Reduced Parameters
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Created Actual Molar Volume of Real Gas given Wohl Parameter a, and Reduced and Critical Parameters
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Created Actual Molar Volume of Real Gas given Wohl Parameter b and Actual and Reduced Parameters
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Created Actual Molar Volume of Real Gas given Wohl Parameter b and Reduced and Critical Parameters
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Created Actual Molar Volume of Real Gas given Wohl Parameter c and Actual and Reduced Parameters
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Created Actual Molar Volume of Real Gas given Wohl Parameter c and Reduced and Critical Parameters
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Created Actual Molar Volume of Real Gas using Critical and Reduced Volume
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Created Actual Molar Volume of Wohl's Real Gas using other Actual and Reduced Parameters
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Created Actual Molar Volume of Wohl's Real Gas using other Critical and Reduced Parameters
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Created Actual Pressure of Real Gas given Clausius Parameter a, Reduced and Actual Parameters
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Created Actual Pressure of Real Gas given Clausius Parameter a, Reduced and Critical Parameters
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Created Actual Pressure of Real Gas given Clausius Parameter b, Actual and Critical Parameters
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Created Actual Pressure of Real Gas given Clausius Parameter b, Reduced and Actual Parameters
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Created Actual Pressure of Real Gas given Clausius Parameter b, Reduced and Critical Parameters
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Created Actual Pressure of Real Gas given Clausius Parameter c, Actual and Critical Parameters
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Created Actual Pressure of Real Gas given Clausius Parameter c, Reduced and Actual Parameters
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Created Actual Pressure of Real Gas given Clausius Parameter c, Reduced and Critical Parameters
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Created Actual Pressure of Real Gas using Critical and Reduced Pressure
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Created Actual Pressure of Real Gas given Wohl Parameter a, and Reduced and Actual Parameters
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Created Actual Pressure of Real Gas given Wohl Parameter a, and Reduced and Critical Parameters
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Created Actual Pressure of Real Gas given Wohl Parameter b and Reduced and Actual Parameters
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Created Actual Pressure of Real Gas given Wohl Parameter b and Reduced and Critical Parameters
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Created Actual Pressure of Real Gas given Wohl Parameter c and Reduced and Actual Parameters
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Created Actual Pressure of Real Gas given Wohl Parameter c and Reduced and Critical Parameters
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Created Actual Pressure of Real Gas using Reduced Wohl Equation given Actual and Critical Parameters
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Created Actual Pressure of Real Gas using Reduced Wohl Equation given Reduced and Critical Parameters
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Created Actual Pressure of Wohl's Real Gas using other Actual and Reduced Parameters
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Created Actual Pressure of Wohl's Real Gas using other Critical and Reduced Parameters
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Created Actual Temperature of Real Gas given Clausius Parameter a, Actual and Critical Parameters
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Created Actual Temperature of Real Gas given Clausius Parameter a, Reduced and Actual Parameters
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Created Actual Temperature of Real Gas given Clausius Parameter a, Reduced and Critical Parameters
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Created Actual Temperature of Real Gas given Clausius Parameter b, Actual and Critical Parameters
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Created Actual Temperature of Real Gas given Clausius Parameter b, Reduced and Actual Parameters
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Created Actual Temperature of Real Gas given Clausius Parameter b, Reduced and Critical Parameters
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Created Actual Temperature of Real Gas given Clausius Parameter c, Actual and Critical Parameters
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Created Actual Temperature of Real Gas given Clausius Parameter c, Reduced and Actual Parameters
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Created Actual Temperature of Real Gas given Clausius Parameter c, Reduced and Critical Parameters
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Created Actual Temperature of Real Gas using Critical and Reduced Temperature
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Created Actual Temperature of Real Gas given Wohl Parameter a, and Reduced and Actual Parameters
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Created Actual Temperature of Real Gas given Wohl Parameter a, and Reduced and Critical Parameters
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Created Actual Temperature of Real Gas given Wohl Parameter b and Reduced and Actual Parameters
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Created Actual Temperature of Real Gas given Wohl Parameter b and Reduced and Critical Parameters
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Created Actual Temperature of real gas given Wohl parameter c and reduced and actual parameters
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Created Actual Temperature of Real Gas given Wohl Parameter c and Reduced and Critical Parameters
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Created Actual Temperature of Wohl's Real Gas using other Actual and Reduced Parameters
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Created Actual Temperature of Wohl's Real Gas using other Critical and Reduced Parameters
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Created Actual Volume of Real Gas using Clausius Parameter b, Critical and Actual Parameters
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Created Actual Volume of Real Gas using Clausius Parameter b, Reduced and Actual Parameters
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Created Actual Volume of Real Gas using Clausius Parameter b, Reduced and Critical Parameters
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Created Actual Volume of Real Gas using Clausius Parameter c, Critical and Actual Parameters
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Created Actual Volume of Real Gas using Clausius Parameter c, Reduced and Actual Parameters
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Created Actual Volume of Real Gas using Clausius Parameter c, Reduced and Critical Parameters
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Created Actual Volume of Real Gas using Critical and Reduced Volume
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Created Critical Volume of Real Gas using Actual and Reduced Volume
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Verified Air Inlet Temperature based on Adiabatic Saturation Temperature
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Verified Heat Transfer Coefficient based on Wet Bulb Temperature
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Verified Inlet Air Humidity based on Adiabatic Saturation Temperature
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Verified Latent Heat of Air based on Wet Bulb Temperature
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Verified Mass Transfer Coefficient based on Wet Bulb Temperature
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8 More Adiabatic Saturation Temperature and Wet Bulb Temperature Calculators
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Created Allred Rochow's Electronegativity from Mulliken's Electronegativity
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Created Allred Rochow's Electronegativity from Pauling's Electronegativity
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Created Allred Rochow's Electronegativity given IE and EA
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Created Allred Rochow's Electronegativity of Element
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Created Allred Rochow's Electronegativity using Bond Energies
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Created Covalent Radius from Allred Rochow's Electronegativity
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Created Effective Nuclear Charge from Allred Rochow's Electronegativity
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Created Electron Affinity of Element using Allred Rochow's Electronegativity
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Created Ionization Energy using Allred Rochow's Electronegativity
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Created Atmospheric Pressure of Water at Boiling Temperature using Antoine Equation
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Created Boiling Temperature of Water for Atmospheric Pressure using Antoine Equation
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4 More Antoine Equation Calculators
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Verified Area under Curve for Drug Administered Intravenous
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Verified Area under Curve for Drug Administered Orally
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Verified Area under Curve Given Average Plasma Concentration
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Verified Area under Curve given Dose and Volume of Distribution
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Verified Area under Curve given Volume of Plasma Cleared
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Verified Area under Curve of Drug for Dosage Type A
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Verified Area under Curve of Drug for Dosage Type B
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Verified Average Plasma Concentration given Area under Curve
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Verified Affluence Count by IPAT Equation
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Verified Drake's Equation for Number of Planets with Intelligent Communicative Extraterrestrial Life
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Verified Human Impact on Environment by IPAT Equation
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Verified Instantaneous Growth Rates of Predator using Lotka Volterra Equation
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Verified Instantaneous Growth Rates of Prey using Lotka Volterra Equation
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Verified Net Biomass
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Verified Net Primary Production
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Verified Population Count by IPAT Equation
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Verified Residence Time of Gas
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Verified Technology Count by IPAT Equation
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Created Atomic Packing Factor in Terms of Particle Radius
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Created Atomic Packing Factor in Terms of Volume of Particle and Unit Cell
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Created Atomic Packing Factor of BCC
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Created Atomic Packing Factor of BCC in Terms of Particle Radius
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Created Atomic Packing Factor of FCC
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Created Atomic Packing Factor of FCC in Terms of Particle Radius
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Created Atomic Packing Factor of SCC
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Created Atomic Packing Factor of SCC in Terms of Particle Radius
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Created Atomicity given Average Thermal Energy of Linear Polyatomic Gas Molecule
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Created Atomicity given Average Thermal Energy of Non-linear Polyatomic Gas Molecule
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Created Atomicity given Internal Molar Energy of Linear Molecule
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Created Atomicity given Internal Molar Energy of Non-Linear Molecule
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Created Atomicity given Molar Heat Capacity at Constant Pressure and Volume of Linear Molecule
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Created Atomicity given Molar Heat Capacity at Constant Pressure and Volume of Non-Linear Molecule
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Created Atomicity given Molar Heat Capacity at Constant Pressure of Linear Molecule
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Created Atomicity given Molar Heat Capacity at Constant Pressure of Non-Linear Molecule
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Created Atomicity given Molar Heat Capacity at Constant Volume of Linear Molecule
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Created Atomicity given Molar Heat Capacity at Constant Volume of Non-Linear Molecule
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Created Atomicity given Molar Vibrational Energy of Linear Molecule
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Created Atomicity given Molar Vibrational Energy of Non-Linear Molecule
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Created Atomicity given Number of modes in Linear Molecule
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Created Atomicity given Number of modes in Non-Linear Molecule
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Created Atomicity given Ratio of Molar Heat Capacity of Linear Molecule
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Created Atomicity given Ratio of Molar Heat Capacity of Non-Linear Molecule
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Created Atomicity given Vibrational Degree of Freedom in Linear Molecule
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Created Atomicity given Vibrational Degree of Freedom in Non-Linear Molecule
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Created Atomicity given Vibrational Energy of Linear Molecule
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Created Atomicity given Vibrational Energy of Non-Linear Molecule
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Created Atomicity given Vibrational Mode of Linear Molecule
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Created Atomicity given Vibrational Mode of Non-Linear Molecule
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Created Average Velocity of Gas given Pressure and Density in 2D
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Created Average Velocity of Gas given Pressure and Volume in 2D
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Created Average Velocity of Gas given Root Mean Square Speed in 2D
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Created Average Velocity of Gas given Temperature in 2D
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5 More Average Velocity of Gas Calculators
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Verified Final Number of Moles of Gas by Avogadro's Law
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Verified Final Volume of Gas by Avogadro's Law
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Verified Initial Number of Moles of Gas by Avogadro's Law
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Verified Initial Volume of Gas by Avogadro's law
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2 More Avogadro's Law Calculators
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Verified Colony Forming Unit of Bacteria
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Verified Dilution Factor of Bacteria
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Verified Growth Rate Constant of Bacteria
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Verified Growth Rate of Bacteria
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Verified No. of Bacteria at Time T
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Verified No. of Colonies of Bacteria
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Verified No. of Generation using Generation Time for Bacteria
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Verified Volume of Culture Plate of Bacteria
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Verified Determination of Atomic Mass using Dulong and Pettit's method
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Verified Determination of Atomic Mass using Vapour Density Method
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Verified Equivalent Mass of Metal using Hydrogen Displacement Method
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Verified Relative Atomic Mass of Element
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Verified Relative Molecular Mass of Compound
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22 More Basic Chemistry Calculators
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Verified Change in Number of Moles due to Reaction
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Verified Extent of Reaction given Change in Number of Moles
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Verified Extent of Reaction given Number of Moles Initially and at Equilibrium
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Verified Number of Gram-Atoms of Element
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Verified Number of Moles at Equilibrium given Extent of Reaction
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Verified Number of Moles Initially given Extent of Reaction
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Verified Selectivity
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7 More Basic Formulas Calculators
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Verified Space Time using Molar Feed Rate of Reactant
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Verified Space Time using Space Velocity
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Verified Space Velocity using Molar Feed Rate of Reactant
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Verified Space Velocity using Space Time
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4 More Basic Formulas Calculators
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Verified Shear Force acting on Newtonian Fluid Layer
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Verified Viscosity using Viscometer
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7 More Basic Formulas Calculators
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Created Total Number of Particles given Total Surface Area
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8 More Basic Formulas Calculators
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Created Baffle Spacing given Shell Area and Shell Diameter
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Verified Equivalent Diameter for Square Pitch in Heat Exchanger
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Verified Equivalent Diameter for Triangular Pitch in Heat Exchanger
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Created Friction Factor in Plate Type Heat Exchanger
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Verified Heat Exchanger Volume for Air Separation Applications
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Verified Heat Exchanger Volume for Hydrocarbon Applications
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Verified Number of Transfer Units for Plate Heat Exchanger
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Verified Number of Tubes in Shell and Tube Heat Exchanger
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Created Pressure Drop in Plate Type Heat Exchanger given Reynolds Number
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Verified Pressure Drop of Vapor in Condensers given Vapors on Shell Side
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Verified Provision for Thermal Expansion and Contraction in Heat Exchanger
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Verified Pumping Power Required in Heat Exchanger Given Pressure Drop
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Verified Shell Area for Heat Exchanger
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Created Shell Diameter Given Shell Area and Baffle Spacing and Tube Pitch
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Verified Shell Side Pressure Drop in Heat Exchanger
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Verified Stack Design Pressure Draft for Furnace
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Verified Stack Height of Furnace given Design Pressure and Flue Gas Temperature
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Verified Tube Side Pressure Drop in Heat Exchanger for Laminar Flow
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Verified Tube Side Pressure Drop in Heat Exchanger for Turbulent Flow
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30 More Basic Formulas of Heat Exchanger Designs Calculators
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Verified Fanning Friction Factor given Colburn J-Factor
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Verified Heat Transfer Coefficient given Local Heat Transfer Resistance of Air Film
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Verified Internal Diameter of Pipe given Heat Transfer Coefficient for Gas in Turbulent Motion
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Verified Reynolds Number given Colburn Factor
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Verified Wetted Perimeter given Hydraulic Radius
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12 More Basics of Heat Transfer Calculators
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Verified Liquid Viscosity Based On Hagen Poiseuille Equation
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Verified Tortuosity Factor of Pores
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14 More Basics of Membrane Separation Processes Calculators
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Verified Radiation Thermal Resistance
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Verified Temperature Difference using Thermal Analogy to Ohm's Law
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11 More Basics of Modes of Heat Transfer Calculators
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Verified Area under C-Pulse Curve
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Verified Exit Age Distribution based on Mean Residence Time
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Verified Exit Age Distribution Curve from C Pulse Curve
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Verified F Curve
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Verified Initial Concentration of Reactant in Plug Flow Reactant with Negligible Density Changes
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Verified Mean of C Pulse Curve
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Verified Rate Constant for Plug Flow Reactor using Space Time for Negligible Density Changes
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Verified Space Time for Plug Flow Reactor with Negligible Density Changes
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Verified Volume of Reactor based on Exit Age Distribution
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Verified Volumetric Flow Rate based on Mean Pulse Curve
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Verified Aniline Point
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Verified API Gravity
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Verified BMCI Number
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Verified Characterisation Factor
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Verified Molal Average Boiling Point Based on Characterisation Factor
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Verified Saybolt Method Viscosity
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Verified Viscosity Index Mixture
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2 More Basics of Petrochemicals Calculators
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Verified Beer-Lambert law given Intensity of Radiation
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Verified Intensity of Incident Radiation
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Verified Intensity of Transmitted Radiation
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Verified Molar Extinction Coefficient given Intensities of Radiation
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11 More Beer Lambert law Calculators
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Created Berthelot parameter b of Real Gas
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Created Berthelot Parameter b of Real Gas given Critical and Reduced Parameters
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Created Berthelot Parameter of Real Gas
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Created Berthelot Parameter of Real Gas given Critical and Reduced Parameters
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Created Critical Molar Volume using Modified Berthelot Equation given Reduced and Actual Parameters
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Created Critical Pressure using Modified Berthelot Equation given Reduced and Actual Parameters
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Created Critical Temperature using Modified Berthelot Equation given Reduced and Actual Parameters
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Created Molar Volume of Real Gas using Berthelot Equation
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Created Molar Volume of Real Gas using Berthelot Equation given Critical and Reduced Parameters
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Created Molar Volume using Modified Berthelot Equation given Critical and Actual Parameters
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Created Molar Volume using Modified Berthelot Equation given Critical and Reduced Parameters
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Created Molar Volume using Modified Berthelot Equation given Reduced and Actual Parameters
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Created Pressure of Real Gas using Berthelot Equation
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Created Pressure of Real Gas using Berthelot Equation given Critical and Reduced Parameters
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Created Pressure using Modified Berthelot Equation given Reduced and Actual Parameters
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Created Reduced Molar Volume using Modified Berthelot Equation given Critical and Actual Parameters
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Created Reduced Pressure using Modified Berthelot Equation given Actual Parameters
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Created Reduced Temperature using Modified Berthelot Equation given Actual Parameters
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Created Temperature of Real Gas using Berthelot Equation
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Created Temperature of Real Gas using Berthelot Equation given Critical and Reduced Parameters
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Created Temperature using Modified Berthelot Equation given Reduced and Actual Parameters
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Verified Van Der Waals Interaction Energy
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2 More BET Adsorption Isotherm Calculators
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Verified Bioavailability given Drug Purity
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Verified Bioavailability given Effective and Administrative Dose
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Verified Bioavailability given Rate of Administration and Dosing Interval
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Verified Bioavailability of Drug
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Verified Heat Transfer Coefficient for Forced Convection Local Boiling Inside Vertical Tubes
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Verified Heat Transfer Coefficient given Biot Number
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Verified Modified Heat of Vaporization
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Verified Modified Heat Transfer Coefficient under Influence of Pressure
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Verified Radiation Heat Transfer Coefficient
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Verified Saturated Temperature given Excess Temperature
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Verified Surface Temperature given Excess Temperature
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Verified Total Heat Transfer Coefficient
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6 More Boiling Calculators
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Verified Final Pressure of Gas by Boyle's Law
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Verified Final Volume of Gas from Boyle's Law
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Verified Initial pressure of gas by Boyles Law
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Verified Initial Volume of Gas by Boyle's Law
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Verified Bundle Diameter for Four Tube Pass Triangular Pitch in Heat Exchanger
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Verified Bundle Diameter for One Tube Pass Triangular Pitch in Heat Exchanger
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Verified Bundle Diameter for Six Tube Pass Triangular Pitch in Heat Exchanger
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Verified Bundle Diameter for Two Tube Pass Triangular Pitch in Heat Exchanger
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Created Bundle Diameter given Shell Diameter and Shell Clearance
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7 More Bundle Diameter in Heat Exchanger Calculators
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Verified Bottom Force given Buoyant Force and Top Force
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Verified Bottom Force on Plate
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Verified Buoyant Force given Bottom and Top Force
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Verified Buoyant Force given Volume of Body
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Verified Buoyant Force on Flat Plate of Uniform Thickness
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Verified Submerged Volume given Weight of Fluid Body
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Verified Top Force given Buoyant Force and Bottom Force
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Verified Top Force on Plate
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Verified Volume of Body given Buoyant Force
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Verified Volume of Plate
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Verified Weight of Submerged Portion of Floating Body
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Verified Capacity Factor given Partition Coefficient and Volume of Mobile and Stationary Phase
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Verified Capacity Factor given Retention Volume and Unretained Volume
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Verified Capacity Factor of Solute 1 given Relative Retention
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Verified Capacity Factor of Solute 2 given Relative Retention
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2 More Capacity factor Calculators
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Verified Degree of Hydrolysis in Salt of Weak Base and Strong Base
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12 More Cationic and Anionic Salt Hydrolysis Calculators
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Verified Concentration of Radical formed during Chain Propagation Step given kw and kg
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Verified Concentration of Radical in Non-Stationary Chain Reactions
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2 More Chain Reactions Calculators
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Verified Change in Retention Time given Half of Average Width of Peaks
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Verified Change in Retention Time given Resolution and Average Width of Peak
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Verified Change in Retention Volume given Resolution and Average Width of Peak
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Verified Final Temperature by Charles's Law
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Verified Final Volume of Gas by Charles's law
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Verified Initial Temperature by Charles's Law
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Verified Initial Volume by Charles's law
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Verified Temperature in Degree Celsius by Charles's Law
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Verified Volume at Temperature 0 Degree Celsius from Charles's Law
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Verified Volume at Temperature t Degree Celsius by Charles's law
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Verified Cell Potential given Change in Gibbs Free Energy
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Verified Classical Part of Gibbs Free Entropy given Electric Part
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Verified Classical Part of Helmholtz Free Entropy given Electric Part
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Verified Entropy given Internal Energy and Helmholtz Free Entropy
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Verified Gibbs Free Energy given Gibbs Free Entropy
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Verified Gibbs Free Entropy
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Verified Gibbs Free Entropy given Helmholtz Free Entropy
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Verified Helmholtz Free Energy given Helmholtz Free Entropy and Temperature
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Verified Helmholtz Free Entropy
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Verified Helmholtz Free Entropy given Helmholtz Free Energy
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Verified Volume given Gibbs and Helmholtz Free Entropy
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3 More Chemical Thermodynamics Calculators
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Created August Roche Magnus Formula
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Created Boiling Point given Enthalpy using Trouton's Rule
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Created Boiling Point using Trouton's Rule given Latent Heat
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Created Boiling Point using Trouton's Rule given Specific Latent Heat
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Created Enthalpy of Vaporization using Trouton's Rule
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Created Enthalpy using Integrated Form of Clausius-Clapeyron Equation
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Created Entropy of Vaporization using Trouton's Rule
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Created Final Pressure using Integrated Form of Clausius-Clapeyron Equation
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Created Final Temperature using Integrated Form of Clausius-Clapeyron Equation
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Created Initial Pressure using Integrated Form of Clausius-Clapeyron Equation
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Created Initial Temperature using Integrated Form of Clausius-Clapeyron Equation
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Created Pressure for Transitions between Gas and Condensed Phase
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Created Ratio of Vapour Pressure using Integrated Form of Clausius-Clapeyron Equation
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Created Saturation Vapor Pressure near Standard Temperature and Pressure
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Created Specific Latent Heat of Evaporation of Water near Standard Temperature and Pressure
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Created Specific Latent Heat using Integrated Form of Clausius-Clapeyron Equation
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Created Specific Latent Heat using Trouton's Rule
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Created Temperature for Transitions
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Created Temperature in Evaporation of Water near Standard Temperature and Pressure
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1 More Clausius Clapeyron Equation Calculators
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Created Clausius Parameter b given Critical Parameters
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Created Clausius Parameter b given Pressure, Temperature and Molar Volume of Real Gas
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Created Clausius Parameter b given Reduced and Actual Parameters
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Created Clausius Parameter b given Reduced and Critical Parameters using Clausius Equation
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Created Clausius Parameter c given Critical Parameters
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Created Clausius Parameter c given Reduced and Actual Parameters
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Created Clausius Parameter given Critical Parameters
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Created Clausius Parameter given Pressure, Temperature and Molar Volume of Real Gas
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Created Clausius Parameter given Reduced and Actual Parameters
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Created Clausius Parametera given Reduced and Critical Parameters using Clausius Equation
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Verified Apparent Value of Michaelis Menten Constant in Presence of Competitive Inhibition
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Verified Dissociation Constant for Competitive Inhibition of Enzyme Catalysis
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Verified Dissociation Constant in Competitive Inhibition given Maximum Rate of System
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Verified Dissociation Constant of Enzyme given Modifying Factor of Enzyme
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Verified Dissociation Constant of Enzyme Substrate Complex given Modifying Factor of Enzyme Substrate
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Verified Enzyme Substrate Complex Concentration for Competitive Inhibition of Enzyme Catalysis
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Verified Final Rate Constant for Competitive Inhibition of Enzyme Catalysis
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Verified Inhibitor Concentration for Competitive Inhibition of Enzyme Catalysis
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Verified Inhibitor Concentration in Competitive Inhibition given Enzyme Substrate Complex Concentration
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Verified Inhibitor Concentration in Competitive Inhibition given Maximum Rate of System
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Verified Initial Enzyme Concentration of Competitive Inhibition of Enzyme Catalysis
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Verified Initial Enzyme in Competitive Inhibition given Enzyme Substrate Complex Concentration
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Verified Initial Rate in Competitive Inhibition given Maximum Rate of system
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Verified Initial Rate of System of Competitive Inhibition of Enzyme Catalysis
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Verified Michaelis Constant for Competitive Inhibition of Enzyme Catalysis
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Verified Michaelis Constant in Competitive Inhibition given Enzyme Substrate Complex Concentration
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Verified Michaelis Constant in Competitive Inhibition given Maximum Rate of System
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Verified Modifying Factor of Enzyme
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Verified Substrate Concentration given Apparent value of Michaelis Menten Constant
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Verified Substrate Concentration given Modifying Factor in Michaelis Menten Equation
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Verified Substrate Concentration in Competitive Inhibition given Enzyme Substrate Complex Concentration
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Verified Substrate Concentration in Competitive Inhibition given Maximum Rate of System
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Verified Substrate Concentration of Competitive Inhibition of Enzyme Catalysis
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Verified Enzyme Catalyst Concentration given Forward, Reverse, and Catalytic Rate Constants
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Verified Enzyme Substrate Complex Concentration given Dissociation Rate Constant
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Verified Enzyme Substrate Complex Concentration given Rate Constant and Initial Rate
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Verified Enzyme Substrate Complex Concentration in Instantaneous Chemical Equilibrium
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Verified Inhibitor Concentration given Apparent Initial Enzyme Concentration
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Verified Inhibitor Concentration given Enzyme Substrate Modifying Factor
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Verified Inhibitor Concentration given Modifying Factor of Enzyme
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Verified Inhibitor Concentration given Modifying Factor of Enzyme Substrate Complex
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Verified Initial Enzyme Concentration at Low Substrate Concentration
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Verified Initial Enzyme Concentration given Catalytic Rate Constant and Dissociation Rate Constants
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Verified Initial Enzyme Concentration given Dissociation Rate Constant
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Verified Initial Enzyme Concentration given Rate Constant and Maximum Rate
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Verified Initial Enzyme Concentration in Enzymatic Reaction Mechanism
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Verified Substrate Concentration given Catalytic Rate Constant and Dissociation Rate Constants
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Verified Substrate Concentration given Catalytic Rate Constant and Initial Enzyme Concentration
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Verified Substrate Concentration given Dissociation Rate Constant
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Verified Substrate Concentration given Forward, Reverse, and Catalytic Rate Constants
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Verified Substrate Concentration given Maximum Rate and Dissociation Rate Constant
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Verified Substrate Concentration given Maximum Rate at Low Concentration
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Verified Substrate Concentration if Michaelis Constant is very Large than Substrate Concentration
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Verified Substrate Concentration in Enzymatic Reaction Mechanism
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Verified Concentration of Anodic Electrolyte of Concentration Cell without Transference
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Verified Concentration of Anodic Electrolyte of Dilute Concentration Cell without Transference
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Verified Concentration of Cathodic Electrolyte of Concentration Cell without Transference
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Verified Concentration of Cathodic Electrolyte of Dilute Concentration Cell without Transference
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Verified Concentration of Electrolyte given Fugacity
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Verified Molality given Ionic Activity and Activity Coefficient
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Verified Molality of Anodic Electrolyte of Concentration Cell without Transference
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Verified Molality of Bi-Trivalent Electrolyte given Ionic Strength
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Verified Molality of Bi-Trivalent Electrolyte given Mean Ionic Activity
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Verified Molality of Cathodic Electrolyte of Concentration Cell without Transference
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Verified Molality of Uni-Bivalent Electrolyte given Mean Ionic Activity
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Verified Molality of Uni-Trivalent Electrolyte given Mean Ionic Activity
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Verified Molality of Uni-Univalent Electrolyte given Mean Ionic Activity
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Verified Molarity of Bi-Bivalent Electrolyte given Ionic Strength
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Verified Molarity of Solution given Molar Conductivity
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Verified Molarity of Uni-Bivalent Electrolyte given Ionic Strength
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1 More Concentration of Electrolyte Calculators
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Created Mass of Solvent using Molality
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Created Molarity of Substance
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Created Number of Moles of Solute using Molality
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19 More Concentration Terms Calculators
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Verified Film Thickness given Mass Flow of Condensate
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Verified Film Thickness in Film Condensation
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Verified Heat Transfer Coefficient for Condensation on Flat Plate for Nonlinear Temperature Profile in Film
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Verified Mass Flow of Condensate through any X Position of Film
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Verified Mass Flow Rate through Particular Section of Condensate Film given Reynolds Number of Film
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Verified Viscosity of Film given Mass Flow of Condensate
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Verified Viscosity of Film given Reynolds Number of Film
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Verified Wetted Perimeter given Reynolds Number of Film
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14 More Condensation Calculators
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Verified Area of Cross-Section of Electrode given Conductance and Conductivity
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Verified Conductance given Conductivity
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Verified Conductivity given Conductance
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Verified Conductivity given Molar Volume of Solution
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Verified Distance between Electrode given Conductance and Conductivity
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Verified Limiting Molar Conductivity given Degree of Dissociation
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Verified Molar Conductivity given Conductivity and Volume
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Verified Molar Volume of solution given Molar Conductivity
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Verified Specific Conductance given Molarity
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11 More Conductance and Conductivity Calculators
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Verified Conduction Thermal Resistance in Slab
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5 More Conduction Calculators
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Verified Initial Partial Pressure of Product in Constant Volume Batch Reactor
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Verified Initial Partial Pressure of Reactant in Constant Volume Batch Reactor
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Verified Number of Moles of Reactant Fed to Constant Volume Batch Reactor
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Verified Partial Pressure of Product in Constant Volume Batch Reactor
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Verified Partial Pressure of Reactant in Constant Volume Batch Reactor
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Verified Reactant Concentration in Constant Volume Batch Reactor
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4 More Constant Volume Batch Reactor Calculators
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Verified Boil-Up Ratio
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Verified Bottom Product based on Boil-up Ratio
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Verified Distillate Flowrate based on External Reflux Ratio
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Verified Distillate Flowrate based on Internal Reflux Ratio
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Verified External Reflux Ratio
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Verified Feed Q-Value in Distillation Column
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Verified Internal Liquid Reflux Flowrate based on Internal Reflux Ratio
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Verified Internal Reflux Ratio
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Verified Liquid Reflux Flowrate based on External Reflux Ratio
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Verified Minimum Number of Distillation Stages by Fenske's Equation
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Verified Murphree Efficiency of Distillation Column Based on Vapour Phase
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Verified Vapor Reflux based on Boil-Up Ratio
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1 More Continuous Distillation Calculators
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Verified Correlation for Local Nusselt Number for Laminar Flow on Isothermal Flat Plate
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Verified Correlation for Nusselt Number for Constant Heat Flux
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Verified Drag Coefficient for Bluff Bodies
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Verified Drag Force for Bluff Bodies
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Verified Friction Coefficient given Shear Stress at Wall
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Verified Friction Factor given Reynolds Number for Flow in Smooth Tubes
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Verified Friction Factor given Stanton Number for Turbulent Flow in Tube
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Verified Local Friction Coefficient given Local Reynolds Number
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Verified Local Nusselt Number for Constant Heat Flux given Prandtl Number
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Verified Local Nusselt Number for Plate Heated over its Entire Length
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Verified Local Skin Friction Coefficient for Turbulent Flow on Flat Plates
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Verified Local Stanton Number
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Verified Local Stanton Number given Local Friction Coefficient
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Verified Local Stanton Number given Prandtl Number
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Verified Local Velocity of Sound
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Verified Local Velocity of Sound when Air Behaves as Ideal Gas
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Verified Mass Flow Rate from Continuity Relation for One Dimensional Flow in Tube
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Verified Mass Flow Rate given Mass Velocity
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Verified Mass Velocity
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Verified Mass Velocity given Mean Velocity
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Verified Mass Velocity given Reynolds Number
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Verified Nusselt Number for Plate heated over its Entire Length
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Verified Nusselt Number for Turbulent Flow in Smooth Tube
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Verified Prandtl Number given Recovery Factor for Gases for Laminar Flow
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Verified Recovery Factor
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Verified Recovery Factor for Gases with Prandtl Number near Unity under Laminar Flow
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Verified Recovery Factor for Gases with Prandtl Number near Unity under Turbulent Flow
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Verified Reynolds Number given Friction Factor for Flow in Smooth Tubes
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Verified Reynolds Number given Mass Velocity
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Verified Shear Stress at Wall given Friction Coefficient
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Verified Stanton Number given Friction Factor for Turbulent Flow in Tube
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Verified Bodenstein Number
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Verified Concentration of Reactant for Chemical Conversions for Second Order in Laminar Flow Reactors
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Verified Dispersion using General Axis Expression
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Verified Dispersion using Taylor Expression Formula
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Verified F Curve for Laminar Flow in Pipes for Improper RTD
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Verified F Curve for Laminar Flow in Pipes for Proper RTD
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Verified Mean Residence Time for Improper RTD
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Verified Mean Residence Time for Proper RTD
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Verified Reactant Concentration for Chemical Conversions for Zero Order in Laminar Flow Reactors
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Verified Capital Cost of Project with Capacity Q1 using Sixth Tenth Rule
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Verified Capital Cost of Project with Capacity Q2 using Sixth Tenth Rule
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Verified Cash Flow
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Verified Net Profit
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Verified Total Capital Investment
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Verified Turndown Ratio
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Verified Turnover Ratio
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4 More Cost Estimation Calculators
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Verified Fractional Solute Discharge based on Ratio of Overflow to Underflow
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Verified Fractional Solute Discharge based on Recovery of Solute
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Verified Fractional Solute Discharge Ratio based on Solute Underflow
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Verified Number of Equilibirum Leaching Stages based on Fractional Solute Discharge
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Verified Number of Equilibirum Leaching Stages based on Solute Underflow
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Verified Number of Equilibrium Leaching Stages based on Recovery of Solute
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Verified Ratio of Solute Discharged in Underflow to Overflow
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Verified Ratio of Solution Discharged in Overflow to Underflow
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Verified Ratio of Solvent Discharged in Underflow to Overflow
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Verified Recovery of Solute based on Fractional Solute Discharge
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Verified Recovery of Solute based on Solute Underflow
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Verified Solute Discharged in Overflow based on Ratio of Overflow to Underflow
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Verified Solute Discharged in Overflow based on Ratio of Overflow to Underflow and Solution Discharged
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Verified Solute Discharged in Underflow based on Ratio of Overflow to Underflow
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Verified Solute Discharged in Underflow based on Ratio of Overflow to Underflow and Solution Discharged
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Verified Solute Underflow Entering Column based on Fractional Solute Discharge
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Verified Solute Underflow Entering Column based on Ratio of Overflow to Underflow
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Verified Solute Underflow Entering Column based on Recovery of Solute
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Verified Solute Underflow Leaving Column based on Fractional Solute Discharge
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Verified Solute Underflow Leaving Column based on Ratio of Overflow to Underflow
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Verified Solute Underflow Leaving Column based on Recovery of Solute
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Verified Solution Discharged in Overflow based on Ratio of Overflow to Underflow
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Verified Solution Discharged in Overflow based on Ratio of Overflow to Underflow and Solute Discharged
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Verified Solution Discharged in Underflow based on Ratio of Overflow to Underflow
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Verified Solution Discharged in Underflow based on Ratio of Overflow to Underflow and Solute Discharged
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Created Bond Angle between Bond Pair and Lone Pair of Electrons given P Character
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Created Bond Angle between Bond Pair and Lone Pair of Electrons given S Character
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Created Bond Order for Molecules Showing Resonance
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Created Formal Charge on Atom
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Created Fraction of P Character given Bond Angle
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Created Fraction of S Character given Bond Angle
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Created Number of Bonding Electrons given Formal Charge
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Created Number of Nonbonding Electrons given Formal Charge
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Created Number of Valence Electrons given Formal Charge
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Created Percentage of P Character given Bond Angle
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Created Percentage of S Character given Bond Angle
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Created Total Number of Bonds between all Structures given Bond Order
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Created Total Number of Resonating Structures given Bond Order
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Created Critical Molar Volume of Real Gas using Clausius Equation given Reduced and Actual Parameters
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Created Critical Molar Volume using Clausius Equation given Actual and Critical Parameters
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Created Critical Molar Volume using Clausius Equation given Reduced and Critical Parameters
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Created Critical Molar Volume of Real Gas for Wohl Parameter a, and other Actual and Reduced Parameters
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Created Critical Molar Volume of Real Gas for Wohl Parameter b and other Actual and Reduced Parameters
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Created Critical Molar Volume of Real Gas for Wohl Parameter c and other Actual and Reduced Parameters
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Created Critical Molar Volume of Real Gas using Actual and Reduced Volume
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Created Critical Molar Volume of Real Gas using Wohl Equation given Wohl Parameter a
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Created Critical Molar Volume of Real Gas using Wohl Equation given Wohl Parameter b
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Created Critical Molar Volume of Real Gas using Wohl Equation given Wohl Parameter c
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Created Critical Molar Volume of Wohl's Real Gas given other Actual and Reduced Parameters
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Created Critical Molar Volume of Wohl's Real Gas given other Critical Parameters
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Verified Critical Packing Parameter
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Verified Length given Critical Packing Parameter
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Verified Number of Moles of Surfactant given Critical Micelle Concentration
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Verified Optimal Head Group Area given Critical Packing Parameter
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Verified Volume of Surfactant Tail given Critical Packing Parameter
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Created Critical Pressure given Clausius parameter a, Reduced and Actual Parameters
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Created Critical Pressure given Clausius Parameter c, Reduced and Actual Parameters
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Created Critical Pressure of Real Gas given Clausius Parameter a
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Created Critical Pressure of Real Gas given Clausius Parameter b
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Created Critical Pressure of Real Gas given Clausius Parameter c
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Created Critical Pressure of Real Gas using Actual and Reduced Pressure
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Created Critical Pressure of Real Gas using Clausius Equation given Actual and Critical Parameters
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Created Critical Pressure of Real Gas using Clausius Equation given Reduced and Actual Parameters
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Created Critical Pressure of Real Gas using Clausius Equation given Reduced and Critical Parameters
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Created Critical Pressure given Peng Robinson Parameter a, and other Actual and Reduced Parameters
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Created Critical Pressure given Peng Robinson Parameter b and other Actual and Reduced Parameters
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Created Critical Pressure of Real Gas using Peng Robinson Equation given Peng Robinson Parameter a
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Created Critical Pressure of Real Gas using Peng Robinson Equation given Peng Robinson Parameter b
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Created Critical Pressure of Real Gas using Peng Robinson Equation given Reduced and Actual Parameters
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Created Critical Pressure using Peng Robinson Equation given Reduced and Critical Parameters
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Created Critical Temperature for Peng Robinson Equation using Alpha-function and Pure Component Parameter
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Verified Critical Temperature given Inversion Temperature
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Created Critical Temperature given Peng Robinson Parameter a, and other Actual and Reduced Parameters
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Created Critical Temperature given Peng Robinson Parameter b and other Actual and Reduced Parameters
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Created Critical Temperature of Real Gas using Peng Robinson Equation given Peng Robinson Parameter a
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Created Critical Temperature of Real Gas using Peng Robinson Equation given Peng Robinson Parameter b
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Created Critical Temperature using Peng Robinson Equation given Reduced and Actual Parameters
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Created Critical Temperature using Peng Robinson Equation given Reduced and Critical Parameters
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Created Critical Temperature given Clausius Parameter a, Reduced and Actual Parameters
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Created Critical Temperature given Clausius Parameter b, Reduced and Actual Parameters
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Created Critical Temperature given Clausius Parameter c, Reduced and Actual Parameters
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Created Critical Temperature of Real Gas given Clausius Parameter a
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Created Critical Temperature of Real Gas given Clausius Parameter b
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Created Critical Temperature of Real Gas given Clausius Parameter c
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Created Critical Temperature of Real Gas using Actual and Reduced Temperature
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Created Critical Temperature of Real Gas using Clausius Equation given Actual and Critical Parameters
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Created Critical Temperature of Real Gas using Clausius Equation given Reduced and Actual Parameters
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Created Critical Temperature of Real Gas using Clausius Equation given Reduced and Critical Parameters
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Created Critical Temperature of Real Gas using Redlich Kwong Equation given 'a'
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Created Critical Temperature of Real Gas using Redlich Kwong Equation given 'a' and 'b'
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Created Critical Temperature of Real Gas using Redlich Kwong Equation given 'b'
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Created Critical Temperature of Real Gas using Reduced Redlich Kwong Equation
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Created Critical Temperature of Real Gas given Wohl Parameter a. and Other Actual and Reduced Parameters
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Created Critical Temperature of Real Gas given Wohl Parameter b and Other Actual and Reduced Parameters
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Created Critical Temperature of Real Gas using Wohl Equation given Reduced and Actual Parameters
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Created Critical Temperature of Real Gas using Wohl Equation given Reduced and Critical Parameters
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Created Critical Temperature of Real Gas using Wohl Equation given Wohl Parameter a
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Created Critical Temperature of Real Gas using Wohl Equation given Wohl Parameter b
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Created Critical Temperature of Real Gas using Wohl Equation given Wohl Parameter c
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Created Critical Temperature of Real Gas using Wohl Parameter c and other Actual and Reduced Parameters
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Created Critical Temperature of Wohl's Real Gas given Other Actual and Reduced Parameters
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Created Critical Temperature of Wohl's Real Gas given other Critical Parameters
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Verified Volumetric Heat Generation in Current Carrying Electrical Conductor
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2 More Critical Thickness of Insulation Calculators
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Created Critical Volume given Clausius Parameter b, Reduced and Actual Parameters
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Created Critical Volume given Clausius Parameter c, Reduced and Actual Parameters
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Created Critical Volume of Real Gas given Clausius Parameter b
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Created Critical Volume of Real Gas given Clausius Parameter c
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Verified Mass Fraction of Crystalline Components
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Verified Mass Fraction of Crystalline Components given Density
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Verified Mass Fraction of Crystalline Components given Specific Volume
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Verified Mass Fraction of Crystalline Regions
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Verified Total Mass of Specimen
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Verified Total Volume of Crystalline Components given Volume Fraction
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Verified Total Volume of Specimen
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Verified Volume Fraction of Crystalline Components
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Verified Volume Fraction of Crystalline Components given Density
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Verified Degree of Supersaturation given Solution Concentration and Equilibrium Saturation Value
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Created Equilibrium Saturation Value given Solution Concentration and Degree of Saturation
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Verified Kinetic Driving Force in Crystallization given Chemical Potential of Fluid and Crystal
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Verified Number of Particles given Nucleation Rate and Supersaturation Volume and Time
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Verified Solubility Product given Activity Coefficient and Mole Fraction of Species A and B
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Verified Solution Concentration given Degree of Supersaturation and Equilibrium Saturation Value
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Verified Supersaturation Ratio given Partial Pressure for Ideal Gas Condition
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17 More Crystallization Calculators
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Verified Mole Fraction of Gas by Dalton's law
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Verified Partial Pressure of Gas by Dalton's law
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Verified Partial Pressure of Gas to determine Volume-Based Concentration by Dalton's law
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Verified Total Gas Pressure by Dalton's law
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Verified Total Gas Pressure to determine Volume-based Concentration by Dalton's law
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Verified Volume-based concentration by Dalton's law using Concentration of Gas
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Verified Mass of Particle given de Broglie Wavelength and Kinetic Energy
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15 More De Broglie Hypothesis Calculators
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Verified Charge Number of Ion Species using Debey-Huckel Limiting Law
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Verified Debey-Huckel Limiting Law Constant
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Verified Degree of Dissociation using Concentration of Reaction
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Verified Degree of Dissociation when Number of Moles of Products at Equilibrium is Half
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6 More Degree of Dissociation Calculators
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Created Degree of Freedom given Molar Heat Capacity at Constant Pressure
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Created Degree of Freedom given Molar Heat Capacity at Constant Volume
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Created Degree of Freedom given Molar Heat Capacity at Constant Volume and Pressure
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Created Degree of Freedom given Ratio of Molar Heat Capacity
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Created Degree of Freedom in Linear Molecule
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Created Degree of Freedom in Non-Linear Molecule
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Created Density of Gas Particle given Vapour Density
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16 More Density for Gases Calculators
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Created Density given Relative Size of Fluctuations in Particle Density
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Created Density given Thermal Pressure Coefficient, Compressibility Factors and Cp
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Created Density given Thermal Pressure Coefficient, Compressibility Factors and Cv
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Created Density given Volumetric Coefficient of Thermal Expansion, Compressibility Factors and Cp
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Created Density given Volumetric Coefficient of Thermal Expansion, Compressibility Factors and Cv
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Created Density of Gas given Average Velocity and Pressure in 2D
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Created Density of Gas given Most Probable Speed Pressure in 2D
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Created Density of Gas given Root Mean Square Speed and Pressure in 1D
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Created Density of Gas given Root Mean Square Speed and Pressure in 2D
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Created Density of Material given Isentropic Compressibility
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3 More Density of Gas Calculators
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Created Cryoscopic Constant given Depression in Freezing Point
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Created Cryoscopic Constant given Latent Heat of Fusion
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Created Cryoscopic Constant given Molar Enthalpy of Fusion
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Created Depression in Freezing Point given Elevation in Boiling Point
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Created Depression in Freezing Point given Osmotic Pressure
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Created Depression in Freezing Point given Relative Lowering of Vapour Pressure
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Created Depression in Freezing Point given Vapour Pressure
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Created Depression in Freezing Point of Solvent
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Created Freezing Point of Solvent given Cryoscopic Constant and Latent Heat of Fusion
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Created Freezing Point of Solvent given Cryoscopic Constant and Molar Enthalpy of Fusion
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Created Latent Heat of Fusion given Freezing Point of Solvent
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Created Molality given Depression in Freezing Point
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Created Molar Enthalpy of Fusion given Freezing point of solvent
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Created Molar Mass of Solvent given Cryoscopic Constant
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Created Relative Lowering of Vapour Pressure given Depression in Freezing Point
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Created Van't Hoff equation for Depression in Freezing Point of electrolyte
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Created Van't Hoff Factor of Electrolyte given Depression in Freezing Point
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6 More Depression in Freezing Point Calculators
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Verified Instantaneous Fractional Yield
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Verified Number of Moles of Product Formed
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Verified Number of Moles of Reactant Reacted
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Verified Overall Fractional Yield
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Verified Total Product Formed
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Verified Total Reactant Fed
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Verified Total Reactant Reacted
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Verified Total Unreacted Reactant
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Verified Initial Reactant Concentration for First Order Reaction in Vessel i
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Verified Initial Reactant Concentration for First Order Reaction using Molar Feed Rate
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Verified Initial Reactant Concentration for First Order Reaction using Reaction Rate
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Verified Initial Reactant Concentration for Second Order Reaction for Plug Flow or Infinite Reactors
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Verified Molar Feed Rate for First Order Reaction for Vessel i
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Verified Rate Constant for First Order Reaction for Plug Flow or for Infinite Reactors
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Verified Rate Constant for First Order Reaction in Vessel i
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Verified Rate Constant for Second Order Reaction for Plug Flow or Infinite Reactors
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Verified Reactant Concentration for First Order Reaction in Vessel i
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Verified Reactant Concentration for Second Order Reaction for Plug Flow or Infinite Reactors
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Verified Reaction Rate for Vessel i for Mixed Flow Reactors of Different Sizes in Series
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Verified Reaction Rate for Vessel i using Space Time
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Verified Space Time for First Order Reaction for Plug Flow or for Infinite Reactors
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Verified Space Time for First Order Reaction for Vessel i using Molar Flow Rate
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Verified Space Time for First Order Reaction for Vessel i using Reaction Rate
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Verified Space Time for First Order Reaction for Vessel i using Volumetric Flow Rate
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Verified Space Time for First Order Reaction in Vessel i
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Verified Space Time for Second Order Reaction for Plug Flow or Infinite Reactors
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Verified Space Time for Vessel i for Mixed Flow Reactors of Different Sizes in Series
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Verified Volume of Vessel i for First Order Reaction using Molar Feed Rate
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Verified Volume of Vessel i for First Order Reaction using Volumetric Flow Rate
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Verified Volumetric Flow Rate for First Order Reaction for Vessel i
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Verified Critical Speed for Each Deflection
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Verified Diameter of Hollow Shaft Subjected to Maximum Bending Moment
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Verified Diameter of Solid Shaft based on Equivalent Bending Moment
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Verified Diameter of Solid Shaft based on Equivalent Twisting Moment
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Verified Diameter of Solid Shaft Subjected to Maximum Bending Moment
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Verified Equivalent Bending Moment for Hollow Shaft
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Verified Equivalent Bending Moment for Solid Shaft
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Verified Equivalent Twisting Moment for Hollow Shaft
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Verified Equivalent Twisting Moment for Solid Shaft
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Verified Force for Design of Shaft Based on Pure Bending
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Verified Maximum Bending Moment subject to Shaft
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Verified Maximum Deflection due to Each Load
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Verified Maximum Deflection due to Shaft with Uniform Weight
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Verified Maximum Torque for Hollow Shaft
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Verified Maximum Torque for Solid Shaft
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Verified Outside Diameter of Hollow Shaft based on Equivalent Bending Moment
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Verified Outside Diameter of Hollow Shaft based on Equivalent Twisting Moment
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1 More Design of Agitation System Components Calculators
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Verified Cross Sectional Area of Bolt
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Verified Diameter of Anchor Bolt Circle
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Verified Diameter of Bolt given Cross Sectional Area
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Verified Height of Lower Part of Vessel
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Verified Height of Upper Part of Vessel
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Verified Load on Each Bolt
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Verified Maximum Compressive Load
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Verified Maximum Seismic Moment
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Verified Maximum Stress in Horizontal Plate fixed at Edges
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Verified Mean Diameter of Skirt in Vessel
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Verified Number of Bolts
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Verified Stress due to Internal Pressure
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Verified Wind Pressure acting on Upper Part of Vessel
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1 More Design of Anchor Bolt and Bolting Chair Calculators
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Verified Crushing Strength of Key
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Verified Crushing Stress in Key
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Verified Length of Rectangular Key
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Verified Length of Square Key
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Verified Shear Strength of Key
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Verified Tangential Force at Circumference of Shaft
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2 More Design of Key Calculators
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Verified Circumferential Stress (Hoop Stress) in Cylinderical Shell
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Verified Effective Thickness of Conical Head
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15 More Design of Pressure Vessel Subjected to Internal Pressure Calculators
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Verified Circumference of Bottom Plate
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Verified Circumferential Length of Plate
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Verified Effective Area of Roof Plates
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Verified Effective Area of Shell Plates
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Verified Height of Tank given Maximum Pressure
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Verified Maximum Deflection of Corroded Plate Thickness
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Verified Maximum Liquid Pressure on Tank Walls
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Verified Minimum required Total Plate Thickness
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Verified Minimum Thickness of Shell at Bottom
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Verified Minimum Width of Annular Plate
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Verified Number of Layers
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Verified Pressure at Bottom of Tank
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Verified Section Modulus of Wind Girder
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Verified Total Area at Roof Load
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Verified Total Shell Plates required
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Verified Clearance between Shaft and Stuffing Box if Shaft Diameter is Greater than 100mm
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Verified Clearance between Shaft and Stuffing Box if Shaft Diameter is less than equal to 100mm
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Verified Diameter of Bolt under Load
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Verified Diameter of Stud under Load
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Verified Internal Diameter of Stuffing Box
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Verified Load taken by Bolts
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Verified Load taken by Studs
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Verified Thickness of Gland Flange
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Verified Thickness of Stuffing Box Body
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1 More Design of Stuffing Box and Gland Calculators
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Verified Bending Moment to size Vertical Stiffeners
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Verified Diameter of Tank Bottom
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Verified Section Modulus of Stiffener
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Verified Axial Bending Stress due to Wind Load at Base of Vessel
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Verified Compressive Stress due to Vertical Downward Force
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Verified Maximum Bending Moment in Bearing Plate Inside Chair
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Verified Maximum Bending Stress in Base Ring Plate
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Verified Maximum Tensile Stress
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Verified Maximum Wind Moment for Vessel with Total Height Greater than 20m
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Verified Maximum Wind Moment for Vessel with Total Height Less than 20m
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Verified Minimum Width of Base Ring
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Verified Minimum Wind Pressure at Vessel
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Verified Moment Arm for Minimum Weight of Vessel
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Verified Thickness of Base Bearing Plate
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Verified Thickness of Bearing Plate inside Chair
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Verified Total Compressive Load on Base Ring
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Verified Wind Load acting on Lower Part of Vessel
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Verified Wind Load acting on Upper Part of Vessel
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1 More Design Thickness of Skirt Calculators
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Verified Archimedes Number
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Verified Euler Number using Fluid Velocity
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Verified Sommerfeld Number
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Verified Weber Number
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7 More Dimensionless Numbers Calculators
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Verified Concentration using Dispersion where Dispersion Number less than 0.01
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Verified Exit Age Distribution based on Dispersion Number
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Verified Standard Deviation of Spread based on Mean Residence Time for Small Extents of Dispersion
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Verified Variance of Spread of Tracer for Small Extents of Dispersion
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Verified Velocity of Pulse based on Variance of Spread of Tracer
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4 More Dispersion Model Calculators
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Created Distance of Closest Approach using Born Lande equation
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Created Distance of Closest Approach using Born-Lande Equation without Madelung Constant
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Created Distance of Closest Approach using Electrostatic Potential
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Created Distance of Closest Approach using Madelung Energy
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Verified Active Area given Gas Volumetric Flow and Flow Velocity
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Verified Column Diameter Based on Vapor Flowrate and Mass Velocity of Vapor
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Verified Fractional Active Area given Downcomer Area and Total Column Area
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Verified Fractional Active Area given Fractional Downcomer Area
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Verified Internal Reflux Ratio Based on Liquid and Distillate Flowrates
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Verified Internal Reflux Ratio Given External Reflux Ratio
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Verified Maximum Allowable Mass Velocity using Bubble Cap Trays
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Verified Minimum External Reflux given Compositions
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Verified Minimum Internal Reflux given Compositions
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Verified Relative Volatility of Two Components Based on Normal Boiling Point and Latent Heat of Vaporization
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Verified Tower Cross Sectional Area given Active Area
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Verified Tower Cross Sectional Area given Fractional Active Area
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Verified Tower Cross Sectional Area given Gas Volumetric Flow and Flooding Velocity
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28 More Distillation Tower Design Calculators
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Verified Distribution Coefficient of Carrier Liquid from Activity Coefficients
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Verified Distribution Coefficient of Carrier Liquid from Mass Fraction
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Verified Distribution Coefficient of Solute from Activity Coefficient
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Verified Distribution Coefficient of Solute from Mass Fractions
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Verified Mass Ratio of Solute in Extract Phase
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Verified Mass Ratio of Solute in Raffinate Phase
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Verified Mass Ratio of Solvent in Extract Phase
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Verified Mass Ratio of Solvent in Raffinate Phase
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Verified Recovery of Solute in Liquid-Liquid Extraction
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Verified Selectivity of Solute based on Distribution Coefficients
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Verified Selectvity of Solute based on Activity Coefficients
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Verified Selectvity of Solute based on Mole Fractions
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Dose (21)
Verified Administrative Dose given Drug Purity
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Verified Administrative dose given effective dose and bioavailability
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Verified Administrative dose given rate of administration and dosing interval
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Verified Adult Dose of Drug by Clark's Equation
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Verified Adult Dose of Drug by Clark's Equation in Micrograms
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Verified Amount of drug administered given apparent volume
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Verified Amount of drug administered given area under curve
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Verified Amount of drug in given volume of plasma
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Verified Clark's Equation of Dosage
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Verified Clark's Equation of Dosage in Microgram
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Verified Dose given volume of distribution and area under curve
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Verified Dose of A type drug
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Verified Dose of B type drug
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Verified Dose of drug administered intravenous
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Verified Dose of drug administered orally
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Verified Dosing interval given average plasma concentration
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Verified Dosing interval given rate of administration
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Verified Effective dose given bioavailability and administrative dose
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Verified Effective dose given drug purity
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Verified Weight of Patient by Clark's equation
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Verified Weight of Patient in Kilograms by Clark's equation
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12 More Dose Calculators
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Verified Absorption Half-Life of Drug
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Verified Apparent Volume of Drug Distribution
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Verified Concentration of Drug given Rate of Infusion of Drug
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Verified Drug Purity given Administrative Dose and Effective Dose
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Verified Drug Purity given Rate of Administration and Dosing Interval
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Verified Drug Rate Entering Body
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Verified Filtration Rate of Drug
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Verified Fraction of Drug Unbound in Tissue given Apparent Tissue Volume
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Verified Rate of Administration of Drug given Dosing Interval
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Verified Rate of Infusion of Drug
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Verified Reabsorption Rate of Drug
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Verified Relative Bioavailability of Drug
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Verified Renal Clearance of Drug
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Verified Secretion Rate of Drug
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12 More Drug Content Calculators
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Verified Dry Weight of Solid based on Critical to Final Moisture Content for Falling Rate Period
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Verified Drying Surface Area based on Critical to Final Moisture Content for Falling Rate Period
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Verified Drying Surface Area based on Critical to Final Weight of Moisture for Falling Rate Period
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Verified Falling Rate Drying Time from Critical to Final Moisture
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Verified Falling Rate Drying Time from Critical to Final Weight of Moisture
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Verified Final Moisture Content based on Critical to Final Moisture Content for Falling Rate Period
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Verified Final Weight of Moisture based on Critical to Final Weight of Moisture for Falling Rate Period
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Verified Rate of Constant Drying Period based on Critical to Final Moisture Content for Falling Rate Period
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Verified Rate of Constant Drying Period based on Critical to Final Weight of Moisture for Falling Rate Period
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Verified Critical Moisture Content based on Initial Moisture Content for Constant Rate Period
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Verified Critical Weight of Moisture based on Initial Weight of Moisture for Constant Rate Period
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Verified Dry Weight of Solid from Initial to Critical Moisture Content for Constant Rate Period
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Verified Initial Moisture Content based on Critical Moisture Content for Constant Rate Period
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Verified Initial Weight of Moisture based on Critical Weight of Moisture for Constant Rate Period
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6 More Drying from Initial to Critical Moisture Calculators
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Verified Dry Weight of Solid from Initial to Final Moisture Content for Constant Rate Period
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Verified Final Moisture Content based on Initial Moisture Content for Constant Rate Period
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Verified Final Weight of Moisture based on Initial Weight of Moisture for Constant Rate Period
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Verified Initial Moisture Content based on Final Moisture Content for Constant Rate Period
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Verified Initial Weight of Moisture based on Final Weight of Moisture for Constant Rate Period
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6 More Drying from Initial to Final Moisture Calculators
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Verified Dry Weight of Solid based on Initial to Final Moisture Content for Falling Rate Period
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Verified Drying Surface Area based on Initial to Final Moisture Content for Falling Rate Period
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Verified Drying Surface Area based on Initial to Final Weight of Moisture for Falling Rate Period
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Verified Falling Rate Drying Time from Initial to Final Moisture
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Verified Falling Rate Drying Time from Initial to Final Weight of Moisture
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Verified Final Moisture Content based on Initial to Final Moisture Content for Falling Rate Period
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Verified Final Weight of Moisture based on Initial to Final Weight of Moisture for Falling Rate Period
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Verified Rate of Constant Drying Period based on Initial to Final Moisture Content for Falling Rate Period
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Verified Rate of Constant Drying Period based on Initial to Final Weight of Moisture for Falling Rate Period
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Verified Constant Drying Time based on Total Drying Time and Falling Drying Time
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Verified Falling Drying Time based on Constant Drying Time and Total Drying Time
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Verified Total Drying Time based on Constant Drying Time and Falling Drying Time
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Verified Initial Reactant Concentration of Macrofluid in Mixed Flow Reactor at First Order
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Verified Initial Reactant Concentration of Microfluid in Mixed Flow Reactor at First Order
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Verified Initial Reactant Concentration of Microfluid in Mixed Flow Reactor at Zero Order
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Verified Reactant Concentration of Microfluid treated in Mixed Flow Reactor
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5 More Earliness of Mixing,Segregation,RTD Calculators
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Verified Classical Internal Energy given Electrical Internal Energy
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Verified Current Flowing given Mass of Substance
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Verified Electric Part Internal Energy given Classical Part
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Verified Electrochemical Equivalent given Charge and Mass of Substance
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Verified Electrochemical Equivalent given Current and Mass of Substance
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Verified Internal Energy given Classical and Electrical Part
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Verified Work Done by Electrochemical Cell given Cell Potential
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1 More Electrochemical Cell Calculators
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Verified Cell Potential given Electrochemical Work
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Verified Fugacity of Anodic Electrolyte of Concentration Cell without Transference
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Verified Fugacity of Cathodic Electrolyte of Concentration Cell without Transference
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Verified Fugacity of Electrolyte given Activities
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Verified Ionic Activity given Molality of Solution
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Verified Number of Positive and Negative Ions of Concentration Cell with Transference
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Verified pH of Water using Concentration
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Verified pOH of Salt of Strong Base and Weak Acid
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Verified pOH using Concentration of Hydroxide ion
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Verified Quantity of Charges given Mass of Substance
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Verified Time required for Flowing of Charge given Mass and Time
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Verified Total Number of Ions of Concentration Cell with Transference given Valencies
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Verified Valencies of Positive and Negative Ions of Concentration Cell with Transference
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12 More Electrolytes and Ions Calculators
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Created 100 percent Covalent Bond Energy as Arithmetic Mean
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Created 100 percent Covalent Bond Energy as Geometric Mean
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Created 100 percent Covalent Bond Energy given Covalent Ionic Resonance Energy
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Created Actual Bond Energy given Covalent Ionic Resonance Energy
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Created Covalent Ionic Resonance Energy
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Created Covalent Ionic Resonance Energy using Bond Energies
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1 More Electronegativity Calculators
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Verified Electronegativity of element A in kcal per mole
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Verified Electronegativity of element A in KJ mole
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Verified Electronegativity of element B in kcal per mole
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Verified Electronegativity of element B in KJ mole
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3 More Electronegativity Calculators
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Verified Angular Wavenumber
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Verified Eigenvalue of Energy given Angular Momentum Quantum Number
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Verified Spectroscopic Wave Number
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12 More Electronic Spectroscopy Calculators
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Verified Number of Electrons in nth Shell
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Verified Number of Orbitals in nth Shell
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14 More Electrons and Orbits Calculators
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Verified Ionic Mobility given Zeta Potential using Smoluchowski Equation
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Verified Relative Permittivity of Solvent given Zeta Potential
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Verified Viscosity of Solvent given Zeta Potential using Smoluchowski Equation
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Verified Zeta Potential using Smoluchowski Equation
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3 More Electrophoresis and other Electrokinetics Phenomena Calculators
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Created Boiling point of Solvent given Ebullioscopic Constant and Latent Heat of Vaporization
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Created Boiling point of Solvent given Ebullioscopic Constant and Molar Enthalpy of Vaporization
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Created Ebullioscopic Constant given Elevation in Boiling Point
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Created Ebullioscopic Constant using Latent Heat of Vaporization
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Created Ebullioscopic Constant using Molar Enthalpy of Vaporization
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Created Elevation in Boiling Point given Depression in Freezing Point
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Created Elevation in Boiling Point given Osmotic Pressure
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Created Elevation in Boiling Point given Relative Lowering of Vapour Pressure
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Created Elevation in Boiling Point given Vapour Pressure
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Created Elevation in Boiling Point of Solvent
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Created Latent Heat of Vaporization given Boiling point of solvent
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Created Molality given Elevation in Boiling Point
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Created Molar Enthalpy of Vaporization given Boiling Point of Solvent
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Created Molar Mass of Solvent given Ebullioscopic Constant
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Created Osmotic Pressure given Elevation in Boiling Point
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Created Relative Lowering of Vapour Pressure given Elevation in Boiling Point
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Created Van't Hoff Equation for Elevation in Boiling Point of Electrolyte
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Created Van't Hoff Factor of Electrolyte given Elevation in Boiling Point
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6 More Elevation in Boiling Point Calculators
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Verified Elimination Half Life given Volume of Plasma Cleared
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Verified Elimination Half Life of Drug
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Verified Elimination Rate Constant given Area under Curve
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Verified Elimination Rate Constant given Volume of Plasma Cleared
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Verified Elimination Rate Constant of Drug
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Verified Total Clearance of Body
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Verified EMF of Concentration Cell with Transference given Activities
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Verified EMF of Concentration Cell with Transference given Transport Number of Anion
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Verified EMF of Concentration Cell with Transference in Terms of Valencies
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Verified EMF of Concentration Cell without Transference for Dilute Solution given Concentration
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Verified EMF of Concentration Cell without Transference given Activities
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Verified EMF of Concentration Cell without Transference given Concentration and Fugacity
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Verified EMF of Concentration Cell without Transference given Molalities and Activity Coefficient
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3 More EMF of Concentration Cell Calculators
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Verified Fluorescence Quantum Yield
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Verified Fluoroscence Quantum Yield given Phosphorescence Quantum Yield
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Verified Fluorosence Intensity at Low Concentration of Solute
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Verified Phosphorescence Quantum Yield
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Verified Phosphorescence Quantum Yield given Fluoroscence Quantum Yield
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Verified Phosphorescence Quantum Yield given Triplet Triplet Annhilation Constant
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Verified Singlet Life Time
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Verified Singlet State Concentration
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Verified Triplet State Concentration
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29 More Emission Spectroscopy Calculators
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Verified Concentration of Enzyme Catalyst by Enzyme Conservation Law
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Verified Concentration of Enzyme Catalyst in Presence of Inhibitor by Enzyme Conservation Law
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Verified Concentration of Enzyme Inhibitor Complex by Enzyme Conservation Law
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Verified Concentration of Enzyme Substrate Complex from Enzyme Conservation Law
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Verified Concentration of Enzyme Substrate Complex in presence of Inhibitor by Enzyme Conservation Law
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Verified Initial Concentration of Enzyme from Enzyme Conservation Law
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Verified Initial Concentration of Enzyme in presence of Inhibitor by Enzyme Conservation Law
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Verified Initial Rate of System given Rate Constant and Enzyme Substrate Complex Concentration
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Verified Initial Reaction Rate at Low Substrate Concentration
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Verified Initial Reaction Rate at Low Substrate Concentration terms of Maximum Rate
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Verified Initial Reaction Rate given Catalytic Rate Constant and Dissociation Rate Constants
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Verified Initial Reaction Rate given Catalytic Rate Constant and Initial Enzyme Concentration
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Verified Initial Reaction Rate given Dissociation Rate Constant
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Verified Initial Reaction Rate in Michaelis Menten kinetics Equation
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Verified Maximum Rate given Dissociation Rate Constant
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Verified Maximum Rate given Rate Constant and Initial Enzyme Concentration
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Verified Maximum Rate of System at Low Substrate Concentration
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Verified Modifying Factor of Enzyme Substrate Complex
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2 More Enzyme Kinetics Calculators
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Verified Equilibrium Concentration of Substance A
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Verified Equilibrium concentration of Substance B
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Verified Equilibrium Concentration of Substance C
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Created Equilibrium Concentration of Substance D
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Verified Equilibrium Constant with respect to Molar Concentrations
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7 More Equilibrium Constant Calculators
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Verified Feed Solute Concentration for N-number of Ideal Stage Extraction
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Verified Feed Solute Concentration for Single Ideal Stage Extraction
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Verified Number of Ideal Equilibrium Extraction Stages
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Verified Raffinate Phase Solute Concentration for N Number of Ideal Stage Extraction
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Verified Raffinate Phase Solute Concentration for Single Ideal Stage Extraction
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Created Average Thermal Energy of Linear Polyatomic Gas Molecule
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Created Average Thermal Energy of Linear Polyatomic Gas Molecule given Atomicity
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Created Average Thermal Energy of Non-linear Polyatomic Gas Molecule
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Created Average Thermal Energy of Non-linear polyatomic Gas Molecule given Atomicity
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Created Heat Capacity
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Created Heat Capacity given Specific Heat Capacity
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Created Internal Molar Energy of Linear Molecule
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Created Internal Molar Energy of Linear Molecule given Atomicity
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Created Internal Molar Energy of Non-Linear Molecule
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Created Internal Molar Energy of Non-Linear Molecule given Atomicity
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Created Molar Vibrational Energy of Linear Molecule
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Created Molar Vibrational Energy of Non-Linear Molecule
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Created Number of Modes in Linear Molecule
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Created Number of Modes in Non-Linear Molecule
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Created Rotational Energy of Linear Molecule
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Created Rotational Energy of Non-Linear Molecule
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Created Specific Heat Capacity given heat capacity
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Created Total Kinetic Energy
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Created Translational Energy
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Created Vibrational Energy Modeled as Harmonic Oscillator
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Created Vibrational Energy of Linear Molecule
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Created Vibrational Energy of Non-Linear Molecule
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Created Vibrational Mode of Linear Molecule
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Created Vibrational Mode of Non-Linear Molecule
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Verified Current Flowing given Mass and Equivalent Weight of Substance
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Verified Electrochemical Equivalent given Equivalent Weight
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Verified Equivalent Weight given Electrochemical Equivalent
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Verified Equivalent weight given Mass and Charge
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Verified Equivalent Weight given Mass and Current Flowing
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Verified Equivalent Weight of First element by Faraday's Second law of Electrolysis
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Verified Equivalent Weight of Second Element by Faraday's Second law of Electrolysis
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Verified Mass of Substance undergoing Electrolysis given Charges
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Verified Mass of Substance undergoing Electrolysis given Charges and Equivalent Weight
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Verified Mass of Substance undergoing Electrolysis given Current and Equivalent Weight
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Verified Mass of Substance undergoing Electrolysis given Current and Time
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Verified Moles of Electron transferred given Electrochemical Work
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Verified Quantity of Charges given Equivalent Weight and Mass of Substance
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Verified Theoretical Mass given Current Efficiency and Actual Mass
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Verified Time Required for Flowing of Current given Mass and Equivalent Weight
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Verified Weight of First Ion by Faraday's Second law of Electrolysis
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Verified Weight of Second Ion by Faraday's Second law of Electrolysis
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1 More Equivalent Weight Calculators
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Verified Initial Reactant Concentration in First Order followed by Zero Order Reaction
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Verified Initial Reactant Concentration using Intermediate for First Order followed by Zero Order Reaction
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Verified Intermediate Concentration for First Order followed by Zero Order Reaction
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Verified Maximum Intermediate Concentration in First Order followed by Zero Order Reaction
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Verified Rate Constant for First Order Reaction in First Order followed by Zero Order Reaction
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Verified Rate Constant for First Order Reaction using Rate Constant for Zero Order Reaction
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Verified Rate Constant for Zero Order Reaction using Rate Constant for First Order Reaction
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Verified Reactant Concentration in First Order followed by Zero Order Reaction
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Verified Time at Max Intermediate in First Order followed by Zero Order Reaction
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Verified Time Interval for First Order Reaction in First Order followed by Zero Order Reaction
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Verified Rate Constant for First Order Irreversible Reaction
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Verified Rate Constant for First Order Irreversible Reaction using log10
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Verified Reaction Time for First Order Irreversible Reaction
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Verified Reaction Time for First Order Irreversible Reaction using log10
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Verified Backward Reaction Rate Constant of First Order Opposed by First Order Reaction
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Verified Equilibrium Reactant Concentration of First Order Opposed by First Order Reaction at given Time t
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Verified Forward Reaction Rate Const of 1st Order Opposed by 1st Order Rxn given Initial Conc of Reactant
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Verified Forward Reaction Rate Constant of First Order Opposed by First Order Reaction
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Verified Initial Concentration of Reactant for First Order Opposed by First Order Reaction
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Verified Product Conc of First Order Opposed by First Order Reaction given Initial Conc of Reactant
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Verified Product Concentration of 1st Order Opposed by 1st Order Reaction at given Time t
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Verified Time taken for 1st Order Opposed by 1st Order Reaction
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Verified Time taken for 1st Order Opposed by 1st Order Reaction given Initial Concentration of Reactant
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8 More First Order Opposed by First Order Reactions Calculators
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Verified Fraction of Liquid in Fluid Kinetics
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Verified Rate Equation of Reactant A for Straight Mass Transfer for Gas Film using Volume of Contactor
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Verified Rate of Reactant A for Straight Mass Transfer for Liquid Film using Surface Area of Contactor
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Verified Rate of Reactant A for Straight Mass Transfer for Liquid Film using Volume of Contactor
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6 More Fluid Fluid Reactions Kinetics Calculators
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Verified Acceleration in X Direction given Average Velocity in Nozzle
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Verified Acceleration in X Direction in Nozzle given Inlet and Outlet Velocity
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Verified Average Velocity given Inlet and Outlet Velocity
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Verified Inlet Area given Inlet Velocity of Fluid in Nozzle
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Verified Inlet Area of Nozzle given Diameter of Nozzle
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Verified Inlet Diameter given Inlet Velocity of Fluid in Nozzle
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Verified Inlet Velocity given Average Velocity
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Verified Inlet Velocity in Nozzle given Inlet Area of Nozzle
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Verified Inlet Velocity in Nozzle given Inlet Diameter of Nozzle
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Verified Outlet Velocity given Average Velocity
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Verified Angular Velocity of Liquid in Rotating Cylinder at Constant Pressure when r is Equal to R
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Verified Angular Velocity of Liquid in Rotating Cylinder just before Liquid Starts Spilling
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Verified Centripetal Acceleration of Fluid Particle Rotating with Constant Angular Velocity
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Verified Equation for Free Surface of Liquid in Rotating Cylinder at Constant Pressure
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Verified Equation for Free Surface of Liquid in Rotating Cylinder at Constant Pressure when r is Equal to R
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Verified Free Surface Isobars in Incompressible Fluid with Constant Acceleration
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Verified Height of Container given Radius and Angular Velocity of Container
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Verified Pressure at Point in Rigid Body Motion of Liquid in Linearly Accelerating Tank
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Verified Slope of Isobar
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Verified Slope of Isobar given Inclination Angle of Free Surface
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Verified Vertical Rise of Free Surface
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Verified Vertical Rise or Drop of Free Surface given Acceleration in X and Z Direction
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Verified Equilibrium Concentration of Aqueous Adsorbate using Freundlich Equation
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Verified Equilibrium Pressure of Gaseous Adsorbate using Freundlich Equation
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7 More Freundlich adsorption isotherm Calculators
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Verified Bending Moment due to Stresses
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Verified Stresses Due to Torsion
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Verified Thermal Stresses
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3 More Fundamental Stress Analysis Calculators
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Verified Rate Equation of Reactant A at Extreme B
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Verified Rate Equation of Reactant B at Extreme A
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11 More G to L Reactions on Solid Catalysts Calculators
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Verified Initial Radiation Intensity
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Verified Monochromatic Absorption Coefficient if Gas is Non-Reflecting
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Verified Monochromatic Transmissivity
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Verified Monochromatic Transmissivity if Gas is Non Reflecting
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Verified Radiation Intensity at given Distance using Beer's Law
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Verified Number of Moles Formed using Reaction Rate of Gas-Solid System
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Verified Reaction Rate in Gas-Solid System
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Verified Reaction Time Interval of Gas-Solid System using Reaction Rate
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Verified Solid Volume using Reaction Rate
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Verified Final Pressure by Gay Lussac's law
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Verified Final Temperature by Gay Lussac's law
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Verified Initial Pressure by Gay Lussac's law
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Verified Initial Temperature by Gay Lussac's law
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Verified Change in Gibbs Free Energy given Cell Potential
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Verified Change in Gibbs Free Energy given Electrochemical Work
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Verified Electric Part of Gibbs Free Entropy given Classical Part
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Verified Entropy given Gibbs Free Entropy
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Verified Gibbs Free Entropy given Classical and Electric Part
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Verified Gibbs Free Entropy given Gibbs Free Energy
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Verified Helmholtz Free Entropy given Gibbs Free Entropy
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Verified Moles of Electron Transferred given Change in Gibbs Free Energy
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Verified Moles of Electron Transferred given Standard Change in Gibbs Free Energy
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Verified Pressure given Gibbs Free Entropy
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Verified Volume given Gibbs Free Entropy
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4 More Gibbs Free Energy and Gibbs Free Entropy Calculators
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Created Number of Components Considering Reactions and Constraints
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Verified Density of First Gas by Graham's Law
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Verified Density of Second Gas by Graham's law
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Verified Molar Mass of First Gas by Graham's law
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Verified Molar Mass of Second Gas by Graham's law
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Verified Rate of Effusion for First Gas by Graham's law
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Verified Rate of Effusion for First Gas given Densities by Graham's law
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Verified Rate of Effusion for Second Gas by Graham's law
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Verified Rate of Effusion for Second Gas given Densities by Graham's law
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Created Hamaker Coefficient
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Created Hamaker Coefficient using Potential Energy in Limit of Closest-Approach
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Created Hamaker Coefficient using Van der Waals Forces between Objects
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Created Hamaker Coefficient using Van der Waals Interaction Energy
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Verified Hamiltonian of System
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Verified Kinetic Operator given Hamiltonian
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Verified Molecular Potential Energy of Molecules
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Verified Molecular Potential Energy of Non-bonded pairs of Atoms
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Verified Potential Energy Operator given Hamiltonian
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Verified Stoichiometric Coefficient for i-th Component in Reaction
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Verified Thermodynamic Beta
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5 More Heat Capacity Calculators
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Verified Total Heat Transfer Coefficient for Long Cylinder
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9 More Heat Exchanger Calculators
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Verified Heat Transfer Coefficient for Condensation Outside Horizontal Tubes
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Verified Heat Transfer Coefficient for Plate Heat Exchanger
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Verified Heat Transfer Coefficient for Subcooling Inside Vertical Tubes
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Verified Heat Transfer Coefficient for Subcooling Outside Horizontal Tubes
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Verified Maximum Heat Flux in Evaporation Process
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Verified Shell Side Heat Transfer Coefficient
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13 More Heat Transfer Coefficient in Heat Exchangers Calculators
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Verified Correction Length for Cylindrical Fin with Non-Adiabatic Tip
Go
Verified Correction Length for Square Fin with Non-Adiabatic Tip
Go
Verified Correction Length for Thin Rectangular Fin with Non-Adiabatic Tip
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Verified Heat Dissipation from Fin Insulated at End Tip
Go
Verified Heat Dissipation from Fin Losing Heat at End Tip
Go
Verified Heat Dissipation from Infinitely Long Fin
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3 More Heat Transfer from Extended Surfaces (Fins) Calculators
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Verified Elastic (Tangent) Modulus using Hughes equation
Go
Verified Frank Bramwell-Hill equation for Pulse Wave Velocity
Go
Verified Mean Arterial Pressure
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Verified Mean Velocity of Blood
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Verified Poiseuille's Equation for Blood Flow
Go
Verified Pressure Drop using Hagen-Poiseuille equation
Go
Verified Pulsatility Index
Go
Verified Pulse Pressure
Go
Verified Pulse Wave Velocity using Moens-Korteweg equation
Go
Verified Rate of Mean Blood Flow
Go
Verified Reynolds Number of Blood in Vessel
Go
Verified Viscosity of Blood
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Verified Concentration of Species in Aqueous Phase by Henry Solubility
Go
Verified Concentration of Species in Gaseous Phase by Dimensionless Henry Solubility
Go
Verified Dimensionless Henry Solubility
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Verified Henry Solubility given Concentration
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Verified Henry Solubility via Aqueous-Phase Mixing Ratio
Go
Verified Molar Mixing Ratio in Aqueous Phase by Henry Solubility
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Verified Partial Pressure of Species in Gas Phase by Henry Solubility
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Verified Absolute Pressure at any Point on Submerged Plate
Go
Verified Absolute Pressure at any Point on Submerged Plate given Intersecting Angle
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Verified Average Pressure given Resultant Force
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Verified Magnitude of Resultant Hydrostatic Force Acting on Curved Surface
Go
Verified Resultant Force Acting on Completely Submerged Plate given Intersecting Angle
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Verified Resultant Force Acting on Completely Submerged Plate given Vertical Distance of Centroid
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Verified Resultant Force Acting on Completely Submerged Rectangular Flat Plate
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Verified Resultant Force Acting on Horizontal Rectangular Surface
Go
Verified Resultant Force Acting on Plane Surface of Completely Submerged Plate
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Verified Resultant Force Acting on Plane Surface of Completely Submerged Plate given Average Pressure
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Verified Amount of Gas taken by Ideal Gas Law
Go
Verified Density of Gas by Ideal Gas law
Go
Verified Final Density of Gas by Ideal Gas Law
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Verified Final Pressure of Gas by Ideal Gas Law
Go
Verified Final Pressure of gas given Density
Go
Verified Final Temperature of Gas by Ideal Gas Law
Go
Verified Final Temperature of Gas given Density
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Verified Final Volume of Gas by Ideal Gas Law
Go
Verified Initial Density of Gas by Ideal Gas Law
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Verified Initial Pressure of Gas by Ideal Gas Law
Go
Verified Initial Pressure of Gas given Density
Go
Verified Initial Temperature of Gas by Ideal Gas law
Go
Verified Initial Temperature of Gas given Density
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Verified Initial Volume of Gas by Ideal Gas Law
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Verified Molecular Weight of Gas by Ideal Gas Law
Go
Verified Molecular Weight of Gas given Density by Ideal Gas Law
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Verified Number of Moles of Gas by Ideal Gas Law
Go
Verified Pressure by Ideal Gas Law
Go
Verified Pressure of Gas given Density by Ideal Gas law
Go
Verified Pressure of Gas given Molecular Weight of Gas by Ideal Gas law
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Verified Temperature of Gas by Ideal Gas Law
Go
Verified Temperature of Gas given Density by Ideal Gas Law
Go
Verified Temperature of Gas given Molecular Weight of Gas by Ideal Gas law
Go
Verified Volume of Gas from Ideal Gas Law
Go
Verified Volume of Gas given Molecular Weight of Gas by Ideal Gas Law
Go
Created Molecular Mass of Liquid forming Immiscible Mixture with Water
Go
Created Molecular Mass of Liquid in Mixture of Two Immiscible Liquids given Weight of Liquids
Go
Created Partial Vapour Pressure of Immiscible Liquid given Partial Pressure of other Liquid
Go
Created Ratio of Molecular Mass of 2 Immiscible Liquids
Go
Created Ratio of Molecular Masses of Water to Liquid forming Immiscible Mixture
Go
Created Ratio of Partial Pressure of 2 Immiscible Liquids given Number of Moles
Go
Created Ratio of Partial Vapour Pressures of 2 Immiscible Liquids given Weight and Molecular Mass
Go
Created Ratio of Partial Vapour Pressures of Water with Liquid forming Immiscible Mixture
Go
Created Ratio of Weights of 2 Immiscible Liquids forming Mixture
Go
Created Ratio of Weights of Water to Liquid forming Immiscible Mixture
Go
Created Total Pressure of Mixture of Liquid with Water given Vapour Pressure of Water
Go
Created Total Pressure of Mixture of Two Immiscible Liquids
Go
Created Total Pressure of Mixture of Water with Liquid given Vapour Pressure
Go
Created Total Vapour Pressure of Mixture of given Partial Pressure of One Liquid
Go
Created Vapour Pressure of Liquid forming Immiscible Mixture with Water
Go
Created Vapour Pressure of Water forming Immiscible Mixture with Liquid
Go
Created Weight of Liquid in Mixture of 2 Immiscible Liquids given Weight of other Liquid
Go
Created Weight of Liquid required to form Immiscible Mixture with Water
Go
Created Weight of Water required to form Immiscible Mixture with Liquid given Weight
Go
Verified Maximum Bending Moment for Impeller Blade
Go
Verified Stress in Blade due to Maximum Bending Moment
Go
Verified Stress in Flat Blade
Go
Created Relative Size of Fluctuations in Particle Density
Go
Created Temperature given Coefficient of Thermal Expansion, Compressibility Factors and Cp
Go
Created Temperature given Coefficient of Thermal Expansion, Compressibility Factors and Cv
Go
Created Temperature given Relative Size of Fluctuations in Particle Density
Go
Created Temperature given Thermal Pressure Coefficient, Compressibility Factors and Cp
Go
Created Temperature given Thermal Pressure Coefficient, Compressibility Factors and Cv
Go
Created Thermal Pressure Coefficient given Compressibility Factors and Cp
Go
Created Thermal Pressure Coefficient given Compressibility Factors and Cv
Go
Created Volume given Relative Size of Fluctuations in Particle Density
Go
Created Volumetric Coefficient of Thermal Expansion given Compressibility Factors and Cp
Go
Created Volumetric Coefficient of Thermal Expansion given Compressibility Factors and Cv
Go
2 More Important Calculator of Compressibility Calculators
Go
Created Molar Mass of Gas given Root Mean Square Speed and Pressure in 2D
Go
14 More Important Formulae on 1D Calculators
Go
Verified Initial Reactant Concentration for First Order Rxn for MFR using Intermediate Concentration
Go
Verified Initial Reactant Concentration for First Order Rxn in MFR at Maximum Intermediate Concentration
Go
Verified Initial Reactant Concentration for First Order Rxn in Series for Maximum Intermediate Concentration
Go
Verified Initial Reactant Concentration for First Order Rxn in Series for MFR using Product Concentration
Go
Verified Initial Reactant Concentration for Two Steps First Order Irreversible Reaction in Series
Go
Verified Initial Reactant Concentration for Two Steps First Order Reaction for Mixed Flow Reactor
Go
Verified Intermediate Concentration for First Order Reaction for Mixed Flow Reactor
Go
Verified Intermediate Concentration for Two Steps First Order Irreversible Reaction in Series
Go
Verified Maximum Intermediate Concentration for First Order Irreversible Reaction in MFR
Go
Verified Maximum Intermediate Concentration for First Order Irreversible Reaction in Series
Go
Verified Product Concentration for First Order Reaction for Mixed Flow Reactor
Go
Verified Rate Constant for First Step First Order Reaction for MFR at Maximum Intermediate Concentration
Go
Verified Rate Constant for Second Step First Order Reaction for MFR at Maximum Intermediate Concentration
Go
Verified Reactant Concentration for Two Steps First Order Reaction for Mixed Flow Reactor
Go
Verified Time at Maximum Intermediate Concentration for First Order Irreversible Reaction in Series
Go
Verified Time at Maximum Intermediate Concentration for First Order Irreversible Reaction in Series in MFR
Go
10 More Important Formulas in Potpourri of Multiple Reactions Calculators
Go
Verified Average Heat Transfer Coefficient given Reynolds Number and Properties at Film Temperature
Go
Verified Condensation Number
Go
Verified Condensation Number for Horizontal Cylinder
Go
Verified Condensation Number for Vertical Plate
Go
Verified Condensation Number given Reynolds Number
Go
Verified Condensation Number when Turbulence is Encountered in Film
Go
Verified Heat Flux in Fully Developed Boiling State for Higher Pressures
Go
Verified Heat Flux in Fully Developed Boiling State for Pressure upto 0.7 Megapascal
Go
8 More Important Formulas of Condensation Number, Average Heat Transfer Coefficient and Heat Flux Calculators
Go
Verified Internal Energy given Gibbs Free Entropy
Go
Verified Standard Cell Potential given Standard Change in Gibbs Free Energy
Go
Verified Standard Change in Gibbs Free Energy given Standard Cell Potential
Go
Created Interplanar Angle for Hexagonal System
Go
Created Interplanar Angle for Orthorhombic System
Go
Created Interplanar Angle for Simple Cubic System
Go
Created Interplanar Distance in Cubic Crystal Lattice
Go
Created Interplanar Distance in Hexagonal Crystal Lattice
Go
Created Interplanar Distance in Monoclinic Crystal Lattice
Go
Created Interplanar Distance in Orthorhombic Crystal Lattice
Go
Created Interplanar Distance in Rhombohedral Crystal Lattice
Go
Created Interplanar Distance in Tetragonal Crystal Lattice
Go
Created Interplanar Distance in Triclinic Crystal Lattice
Go
Verified Capitalized Cost
Go
Verified Future Worth of Annuity
Go
Verified Future Worth of Annuity given Present Annuity
Go
Verified Future Worth of Perpetuity
Go
Verified Present Worth for Initial Replacement
Go
Verified Present Worth of Annuity
Go
Verified Present Worth of Perpetuity
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Verified Present Worth with Salvage Value of Equipment at 2nd Year Investment
Go
Verified Replacement Cost
Go
Verified Initial Key Reactant Concentration with Varying Density,Temperature and Total Pressure
Go
Verified Initial Reactant Concentration using Reactant Conversion with Varying Density
Go
Verified Initial Reactant Conversion using Reactant Concentration with Varying Density
Go
Verified Key Reactant Concentration with Varying Density,Temperature and Total Pressure
Go
Verified Key Reactant Conversion with Varying Density,Temperature and Total Pressure
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Verified Reactant Concentration using Reactant Conversion with Varying Density
Go
3 More Introduction to Reactor Design Calculators
Go
Verified Boyle Temperature given Inversion Temperature
Go
Verified Inversion Temperature given Boyle Temperature
Go
Verified Inversion Temperature given Critical Temperature
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Verified Inversion Temperature given Van der Waals Constants
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Verified Inversion Temperature given Van der Waals Constants and Boltzmann Constant
Go
Created Charge of Ion given Ionic Potential
Go
Created Ionic Potential
Go
Created Radius of Ion given Ionic Potential
Go
Verified Ionic Strength for Bi-Bivalent Electrolyte
Go
Verified Ionic Strength for Bi-Bivalent Electrolyte if Molality of Cation and Anion is Same
Go
Verified Ionic Strength for Uni-Univalent Electrolyte
Go
Verified Ionic Strength of Bi-Trivalent Electrolyte
Go
Verified Ionic Strength of Bi-Trivalent Electrolyte if Molality of Cation and Anion are Same
Go
Verified Ionic Strength of Uni-Bivalent Electrolyte
Go
Verified Ionic Strength of Uni-Bivalent Electrolyte if Molality of Cation and Anion are Same
Go
Verified Ionic Strength using Debey-Huckel Limiting Law
Go
Created Isentropic Compressibility
Go
Created Isentropic Compressibility given Molar Heat Capacity at Constant Pressure and Volume
Go
Created Isentropic Compressibility given Molar Heat Capacity Ratio
Go
Created Isentropic Compressibility given Thermal Pressure Coefficient and Cp
Go
Created Isentropic Compressibility given Thermal Pressure Coefficient and Cv
Go
Created Isentropic Compressibility given Volumetric Coefficient of Thermal Expansion and Cp
Go
Created Isentropic Compressibility given Volumetric Coefficient of Thermal Expansion and Cv
Go
1 More Isentropic Compressibility Calculators
Go
Verified Number of Geometrical Isomers for Symmetrical Molecule with Even Stereocenters
Go
Verified Number of Geometrical Isomers for Symmetrical Molecule with Odd Stereocenters
Go
Verified Number of Geometrical Isomers for Unsymmetrical Molecule
Go
8 More Isomerism Calculators
Go
Created Isothermal Compressibility given Molar Heat Capacity at Constant Pressure and Volume
Go
Created Isothermal Compressibility given Molar Heat Capacity Ratio
Go
Created Isothermal Compressibility given Relative Size of Fluctuations in Particle Density
Go
Created Isothermal Compressibility given Thermal Pressure Coefficient and Cp
Go
Created Isothermal Compressibility given Thermal Pressure Coefficient and Cv
Go
Created Isothermal Compressibility given Volumetric Coefficient of Thermal Expansion and Cp
Go
Created Isothermal Compressibility given Volumetric Coefficient of Thermal Expansion and Cv
Go
Verified Channel Jacket Thickness
Go
Verified Combined Moment of Inertia of Shell and Stiffener per Unit Length
Go
Verified Cross Sectional Area of Stiffening Ring
Go
Verified Depth of Torisperical Head
Go
Verified Design of Shell Thickness Subjected to Internal Pressure
Go
Verified Dished Head Thickness
Go
Verified Jacket Width
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Verified Length of Shell for Jacket
Go
Verified Length of Shell under Combined Moment of Inertia
Go
Verified Maximum Axial Stress in Coil at Junction with Shell
Go
Verified Maximum Equivalent Stress at Junction with Shell
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Verified Maximum Hoop Stress in Coil at Junction with Shell
Go
Verified Required Plate Thickness for Dimple Jacket
Go
Verified Required Thickness for Jacket Closer Member with Jacket Width
Go
Verified Shell Thickness for Critical External Pressure
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Verified Thickness of Bottom Head subjected to Pressure
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Verified Thickness of Half Coil Jacket
Go
Verified Thickness of Jacket Shell for Internal Pressure
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Verified Total Axial Stress in Vessel Shell
Go
Verified Total Hoop Stress in Shell
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Verified Vessel Wall Thickness for Channel Type Jacket
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Verified Kinetic Energy of One Gas Molecule given Boltzmann Constant
Go
4 More Kinetic Energy of Gas Calculators
Go
Verified Extraction Factor at Feed Point Slope of Equilibrium Curve
Go
Verified Extraction Factor at Mean Slope of Equilibrium Curve
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Verified Extraction Factor based on Raffinate Point Slope
Go
Verified Geometric Mean of Equilibrium Line Slope
Go
Verified Number of Extraction Stages by Kremser Equation
Go
Verified Number of Stages for Extraction Factor equal to 1
Go
Verified Fractional Occupancy of Adsorption Sites by Langmuir Adsorption Equation
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4 More Langmuir Adsorption Isotherm Calculators
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Verified Contact Angle Hysteresis
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Verified Interfacial Tension by Laplace Equation
Go
Verified Laplace Pressure
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Verified Laplace Pressure of Bubbles or Droplets using Young Laplace Equation
Go
Verified Laplace Pressure of Curved Surface using Young-Laplace Equation
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Verified Maximum Force at Equilibrium
Go
Verified Parachor Given Molar Volume
Go
Verified Shape Factor using Pendant Drop
Go
1 More Laplace and Surface Pressure Calculators
Go
Created Latent Heat of Evaporation of Water near Standard Temperature and Pressure
Go
Created Latent Heat of Vaporization for Transitions
Go
Created Latent Heat using Integrated Form of Clausius-Clapeyron Equation
Go
Created Latent Heat using Trouton's Rule
Go
Lattice (15)
Created Edge Length using Interplanar Distance of Cubic Crystal
Go
Created Energy per impurity
Go
Created Energy per vacancy
Go
Created Fraction of impurity in lattice
Go
Created Fraction of impurity in lattice terms of Energy
Go
Created Fraction of Vacancy in lattice
Go
Created Fraction of Vacancy in lattice terms of Energy
Go
Created Miller index along X-axis using Weiss Indices
Go
Created Miller index along Y-axis using Weiss Indices
Go
Created Miller index along Z-axis using Weiss Indices
Go
Created Number of lattice containing impurities
Go
Created Number of vacant lattice
Go
Created Weiss Index along X-axis using Miller Indices
Go
Created Weiss Index along Y-axis using Miller Indices
Go
Created Weiss Index along Z-axis using Miller Indices
Go
9 More Lattice Calculators
Go
Created 1D Lattice Direction for Lattice Points
Go
Created 2D Lattice Direction for Lattice Points
Go
Created 3D Lattice Direction for Lattice Points
Go
Created 3D Lattice Direction for points in space which are not Lattice Points
Go
Created 3D Lattice Direction for points in space which are not Lattice Points with respect to lattice points
Go
Created Born Exponent using Born Lande Equation
Go
Created Born Exponent using Born-Lande equation without Madelung Constant
Go
Created Born Exponent using Repulsive Interaction
Go
Created Constant depending on compressibility using Born-Mayer equation
Go
Created Electrostatic Potential Energy between pair of Ions
Go
Created Lattice Energy using Born Lande Equation
Go
Created Lattice Energy using Born-Lande equation using Kapustinskii Approximation
Go
Created Lattice Energy using Born-Mayer equation
Go
Created Lattice Energy using Kapustinskii equation
Go
Created Lattice Energy using Lattice Enthalpy
Go
Created Lattice Energy using Original Kapustinskii equation
Go
Created Lattice Enthalpy using Lattice Energy
Go
Created Minimum Potential Energy of Ion
Go
Created Number of Ions using Kapustinskii Approximation
Go
Created Outer Pressure of Lattice
Go
Created Repulsive Interaction
Go
Created Repulsive Interaction Constant
Go
Created Repulsive Interaction Constant given Madelung constant
Go
Created Repulsive Interaction Constant given Total Energy of Ion and Madelung Energy
Go
Created Repulsive Interaction Constant using Total Energy of Ion
Go
Created Repulsive Interaction using Total Energy of Ion
Go
Created Repulsive Interaction using Total Energy of ion given charges and distances
Go
Created Total Energy of Ion given Charges and Distances
Go
Created Total Energy of Ion in Lattice
Go
Created Volume change of lattice
Go
Verified Column Length given Standard Deviation and Plate Height
Go
Verified Plate Height given Standard Deviation and Length of Column
Go
Verified Standard Deviation given Plate Height and Length of Column
Go
5 More Length of Column Calculators
Go
Verified Axial Bending Stress in Vessel Wall for Unit Width
Go
Verified Bending Stress in Column due to Wind Load
Go
Verified Maximum Combined Stress on Long Column
Go
Verified Maximum Combined Stress on Short Column
Go
Verified Maximum Compressive Load acting on Bracket
Go
Verified Maximum Compressive Load on Remote Bracket due to Dead Load
Go
Verified Maximum Compressive Stress
Go
Verified Maximum Compressive Stress Parallel to Edge of Gusset Plate
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Verified Maximum Pressure on Horizontal Plate
Go
Verified Minimum Area by Base Plate
Go
Verified Minimum Thickness of Base Plate
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Verified Pressure Intensity on under side of Base Plate
Go
2 More Lug or Bracket Support Calculators
Go
Verified Airway Conductance
Go
Verified Airway Resistance
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Verified Function Residual Capacity
Go
Verified Inspiratory capacity of Lung
Go
Verified Total Lung Capacity
Go
Verified Vital Capacity of Lung
Go
Created Madelung Constant given Repulsive Interaction Constant
Go
Created Madelung Constant using Born Lande Equation
Go
Created Madelung Constant using Born-Mayer equation
Go
Created Madelung Constant using Kapustinskii Approximation
Go
Created Madelung Constant using Madelung Energy
Go
Created Madelung Constant using Total Energy of Ion
Go
Created Madelung Constant using Total Energy of Ion given Repulsive Interaction
Go
Created Madelung Energy
Go
Created Madelung Energy using Total Energy of Ion
Go
Created Madelung Energy using Total Energy of Ion given Distance
Go
Verified Piezometric Pressure
Go
2 More Manometers Calculators
Go
Verified Diffusivity by Instanataneous Contact Time in Penetration Theory
Go
Verified Instantaneous Contact Time by Penetration Theory
Go
Verified Instantaneous Mass Transfer Coefficient by Penetration Theory
Go
17 More Mass Transfer Theories Calculators
Go
Verified Mole Fraction of MVC in Distillate from Overall and Component Material Balance in Distillation
Go
Verified Mole Fraction of MVC in Distillate from Overall Component Material Balance in Distillation
Go
Verified Mole Fraction of MVC in Feed from Overall and Component Material Balance in Distillation
Go
Verified Mole Fraction of MVC in Feed from Overall Component Material Balance in Distillation
Go
Verified Mole Fraction of MVC in Residue from Overall and Component Material Balance in Distillation
Go
Verified Mole Fraction of MVC in Residue from Overall Component Material Balance in Distillation
Go
Verified Total Distillate Flowrate of Distillation Column from Overall and Component Material Balance
Go
Verified Total Distillate Flowrate of Distillation Column from Overall Component Material Balance
Go
Verified Total Distillate Flowrate of Distillation Column from Overall Material Balance
Go
Verified Total Feed Flowrate of Distillation Column from Overall Component Material Balance
Go
Verified Total Feed Flowrate of Distillation Column from Overall Material Balance
Go
Verified Total Residue Flowrate of Distillation Column from Overall and Component Material Balance
Go
Verified Total Residue Flowrate of Distillation Column from Overall Component Material Balance
Go
Verified Total Residue Flowrate of Distillation Column from Overall Material Balance
Go
Verified Mean Activity Coefficient for Bi-Trivalent Electrolyte
Go
Verified Mean Activity Coefficient for Uni-Bivalent Electrolyte
Go
Verified Mean Activity Coefficient for Uni-Trivalent Electrolyte
Go
Verified Mean Activity Coefficient for Uni-Univalent Electrolyte
Go
Verified Mean Activity Coefficient using Debey-Huckel Limiting Law
Go
Verified Mean Ionic Activity for Bi-Trivalent Electrolyte
Go
Verified Mean Ionic Activity for Uni-Bivalent Electrolyte
Go
Verified Mean Ionic Activity for Uni-Trivalent Electrolyte
Go
Verified Mean Ionic Activity for Uni-Univalent Electrolyte
Go
Created Mean Square Speed of Gas Molecule given Pressure and Volume of Gas in 1D
Go
Created Mean Square Speed of Gas Molecule given Pressure and Volume of Gas in 2D
Go
1 More Mean Square Speed of Gas Calculators
Go
Verified Membrane Pore Diameter
Go
Verified Membrane Porosity
Go
Created Solute Concentration at Membrane Surface
Go
10 More Membrane Characteristics Calculators
Go
Verified Mass of aggregate enclosed within distance r
Go
Verified Micellar Aggregation Number
Go
Verified Micellar Core Radius given Micellar Aggregation Number
Go
Verified Volume of Hydrophobic Tail given Micellar Aggregation Number
Go
Verified Catalytic Rate Constant from Michaelis Menten Kinetics Equation
Go
Verified Catalytic rate constant given Michaelis Constant
Go
Verified Catalytic Rate Constant if Substrate Concentration is higher than Michaelis Constant
Go
Verified Dissociation Rate Constant from Michaelis Menten kinetics equation
Go
Verified Enzyme Concentration from Michaelis Menten Kinetics equation
Go
Verified Forward Rate Constant given Michaelis Constant
Go
Verified Inhibitor Concentration given Apparent Michaelis Menten Constant
Go
Verified Inhibitor's Dissociation Constant given Michaelis Menten Constant
Go
Verified Initial Enzyme Concentration if Substrate Concentration is Higher than Michaelis Constant
Go
Verified Initial Rate given Apparent value of Michaelis Menten Constant
Go
Verified Initial Reaction Rate of Enzyme given Modifying factor in Michaelis Menten equation
Go
Verified Maximum Rate given Apparent Value of Michaelis Menten Constant
Go
Verified Maximum Rate given Modifying Factor in Michaelis Menten Equation
Go
Verified Maximum Rate if Substrate Concentration is Higher than Michaelis Constant
Go
Verified Maximum Rate of System from Michaelis Menten Kinetics equation
Go
Verified Michaelis Constant at Low Substrate Concentration
Go
Verified Michaelis Constant from Michaelis Menten kinetics equation
Go
Verified Michaelis Constant given Catalytic Rate Constant and Initial Enzyme Concentration
Go
Verified Michaelis Constant given Forward, Reverse, and Catalytic Rate Constants
Go
Verified Michaelis Constant given Maximum Rate at Low Substrate Concentration
Go
Verified Michaelis Constant given Modifying Factor in Michaelis Menten Equation
Go
Verified Michaelis Menten constant given Apparent Michaelis Menten Constant
Go
Verified Modifying Factor of Enzyme in Michaelis Menten Equation
Go
Verified Modifying Factor of Enzyme Substrate Complex in Michaelis Menten Equation
Go
Verified Substrate Concentration from Michaelis Menten Kinetics Equation
Go
Verified Approximate Water Potential of Cell
Go
Verified Bioconcentration Factor
Go
Verified Broad Heritability using Breeder's Equation
Go
Verified Fugacity Capacity of Chemical in Fish
Go
Verified Hardy Weinberg Equation for Predicted Frequency of Homozygous Dominant (AA) Type
Go
Verified Hardy-Weinberg Equilibrium Equation for Predicted Frequency of Heterozygous (Aa) Type
Go
Verified Narrow Heritability using Breeder's equation
Go
Verified Octanol-Water Partition Coefficient
Go
Verified Pressure Potential of Cell given Water and Solute Potential
Go
Verified Rotational Angle of Alpha Helix
Go
Verified Solute Potential of Cell given Water and Pressure Potential
Go
Verified Temperature Coefficient of Resistance of RTD
Go
Verified Wall tension of Vessel using Young-Laplace Equation
Go
11 More Microbiology Calculators
Go
Verified Initial Reactant Concentration for Second Order Reaction using Space Time for Mixed Flow
Go
Verified Initial Reactant Concentration for Zero Order Reaction using Space Time for Mixed Flow
Go
Verified Rate Constant for First Order Reaction using Reactant Concentration for Mixed Flow
Go
Verified Rate Constant for First Order Reaction using Space Time for Mixed Flow
Go
Verified Rate Constant for Second Order Reaction using Reactant Concentration for Mixed Flow
Go
Verified Rate Constant for Second Order Reaction using Space Time for Mixed Flow
Go
Verified Rate Constant for Zero Order Reaction using Space Time for Mixed Flow
Go
Verified Reactant Concentration for Zero Order Reaction using Space Time for Mixed Flow
Go
Verified Reactant Conversion for Zero Order Reaction using Space Time for Mixed Flow
Go
Verified Space Time for First Order Reaction for Mixed Flow
Go
Verified Space Time for First Order Reaction using Reactant Concentration for Mixed Flow
Go
Verified Space Time for Second Order Reaction for Mixed Flow
Go
Verified Space Time for Second Order Reaction using Reactant Concentration for Mixed Flow
Go
Verified Space Time for Zero Order Reaction for Mixed Flow
Go
Verified Initial Reactant Concentration for Second Order Reaction for Mixed Flow
Go
Verified Initial Reactant Concentration for Zero Order Reaction for Mixed Flow
Go
Verified Rate Constant for First Order Reaction for Mixed Flow
Go
Verified Rate Constant for Second Order Reaction for Mixed Flow
Go
Verified Rate Constant for Zero Order Reaction for Mixed Flow
Go
Verified Reactant Conversion for Zero Order Reaction for Mixed Flow
Go
Verified Space Time for First Order Reaction using Rate Constant for Mixed Flow
Go
Verified Space Time for Second Order Reaction using Rate Constant for Mixed Flow
Go
Verified Space Time for Zero Order Reaction using Rate Constant for Mixed Flow
Go
Verified Bound Moisture Content based on Free and Equilibrium Moisture Content
Go
Verified Bound Moisture Content based on Unbound Moisture Content
Go
Verified Equilibrium Moisture Content based on Bound and Unbound Moisture Content
Go
Verified Equilibrium Moisture Content based on Free Moisture Content
Go
Verified Free Moisture Content based on Bound and Unbound Moisture Content
Go
Verified Free Moisture Content based on Equilibrium Moisture Content
Go
Verified Initial Moisture Content based on Bound and Unbound Moisture Content
Go
Verified Initial Moisture Content based on Free and Equlibrium Moisture Content
Go
Verified Unbound Moisture Content based on Bound Moisture Content
Go
Verified Unbound Moisture Content based on Free and Equilibrium Moisture Content
Go
Verified Molality of Solvent of n-solute Solution
Go
Created Molality using Number of Moles and Mass of Solvent
Go
3 More Molality Calculators
Go
Created Molar Heat Capacity at Constant Pressure given Compressibility
Go
Created Molar Heat Capacity at Constant Pressure given Degree of Freedom
Go
Created Molar Heat Capacity at Constant Pressure given Thermal Pressure Coefficient
Go
Created Molar Heat Capacity at Constant Pressure given Volumetric Coefficient of Thermal Expansion
Go
Created Molar Heat Capacity at Constant Pressure of Linear Molecule
Go
Created Molar Heat Capacity at Constant Pressure of Non-Linear Molecule
Go
Created Molar Heat Capacity at Constant Volume given Compressibility
Go
Created Molar Heat Capacity at Constant Volume given Degree of Freedom
Go
Created Molar Heat Capacity at Constant Volume given Thermal Pressure Coefficient
Go
Created Molar Heat Capacity at Constant Volume given Volumetric Coefficient of Thermal Expansion
Go
Created Molar Heat Capacity at Constant Volume of Linear Molecule
Go
Created Molar Heat Capacity at Constant Volume of Non-Linear Molecule
Go
Created Molar Mass given Most Probable Speed and Temperature in 2D
Go
Created Molar Mass of Gas given Average Velocity, Pressure, and Volume in 2D
Go
Created Molar Mass of Gas given most probable Speed, Pressure and Volume in 2D
Go
Created Molar Mass of Gas given Root Mean Square Speed and Pressure in 1D
Go
Created Molar Mass of Gas given Root Mean Square Speed and Temperature in 1D
Go
Created Molar Mass of Gas given Root Mean Square Speed and Temperature in 2D
Go
Created Molar Mass of Gas given Temperature and Average Velocity in 1D
Go
7 More Molar Mass of Gas Calculators
Go
Created Molar Volume of Real Gas using Clausius Equation
Go
Created Molar Volume of Real Gas using Clausius Equation given Reduced and Critical Parameters
Go
Verified Collision Cross Section in Ideal Gas
Go
Verified Collision Frequency in Ideal Gas
Go
Verified Collisional Cross Section
Go
Verified Concentration of Equal Size Particle in Solution using Collision Rate
Go
Verified Cross Sectional Area using Rate of Molecular Collisions
Go
Verified Number Density for A Molecules using Collision Rate Constant
Go
Verified Number of Bimolecular Collision per Unit Time per Unit Volume
Go
Verified Number of Collisions per Second in Equal Size Particles
Go
Verified Reduced Mass of Reactants A and B
Go
Verified Reduced Mass of Reactants using Collision Frequency
Go
Verified Temperature of Molecular Particle using Collision Rate
Go
Verified Vibrational Frequency given Boltzmann's Constant
Go
Verified Viscosity of Solution using Collision Rate
Go
6 More Molecular Reaction Dynamics Calculators
Go
Created Most Probable Velocity of Gas given Pressure and Density in 2D
Go
Created Most Probable Velocity of Gas given Pressure and Volume in 2D
Go
Created Most Probable Velocity of Gas given RMS Velocity in 2D
Go
Created Most Probable Velocity of Gas given Temperature in 2D
Go
4 More Most Probable Velocity of Gas Calculators
Go
Created Covalent Radius given Mulliken's Electronegativity
Go
Created Effective Nuclear Charge given Mulliken's Electronegativity
Go
Created Electron Affinity of element using Mulliken's Electronegativity
Go
Created Ionization Energy of element using Mulliken's Electronegativity
Go
Created Mulliken's Electronegativity from Allred Rochow's Electronegativity
Go
Created Mulliken's Electronegativity from Pauling's Electronegativity
Go
Created Mulliken's Electronegativity given Bond Energies
Go
Created Mulliken's Electronegativity given Effective Nuclear Charge and Covalent Radius
Go
Created Mulliken's Electronegativity of Element
Go
Created Degrees of Freedom of Multi Component System
Go
Created Number of Components of Multi Component System
Go
Created Number of Phases of Multi Component System
Go
Verified Apparent Initial Enzyme Concentration in Presence of Noncompetitive Inhibitor
Go
Verified Apparent Maximum Rate in presence of Noncompetitive Inhibitor
Go
Verified Apparent Michaelis Menten constant given Inhibitor's Dissociation Constant
Go
Verified Dissociation Constant given Apparent Initial Enzyme Concentration
Go
Verified Dissociation Constant given Enzyme Substrate Complex Concentration
Go
Verified Dissociation Constant in presence of Noncompetitive Inhibitor
Go
Verified Inhibitor Concentration in presence of Noncompetitive Inhibitor
Go
Verified Initial Enzyme Concentration in presence of Noncompetitive Inhibitor
Go
Verified Maximum Rate in presence of Noncompetitive Inhibitor
Go
Verified Equivalent Conductance given Normality
Go
Verified Normality given Equivalent Conductance
Go
Verified Specific Conductivity given Equivalent Conductivity and Normality of solution
Go
Created Number Density given Mass Density and Molar Mass
Go
Created Number Density given Molar Concentration
Go
Created Number Density of Particle 1 given Hamaker Coefficient
Go
Created Number Density of Particle 2 given Hamaker Coefficient
Go
Verified Area of Contact for Batch Leaching Operation
Go
Verified Concentration of Saturated Solution in Contact with Solid in Batch Leaching
Go
Verified Concentration of Solute in Bulk Solution at Time t for Batch Leaching
Go
Verified Mass Transfer Coefficient for Batch Leaching
Go
Verified Time of Batch Leaching Operation
Go
Verified Volume of Leaching Solution in Batch Leaching
Go
Verified Decrease of Splicing Potential by Mutant Sequence
Go
Verified Increase of Splicing Potential by Wild-type Sequence
Go
15 More Osmolality Calculators
Go
Verified Actual Mass given Current Efficiency
Go
Verified Excess Pressure given Osmotic Coefficient
Go
Verified Ideal Pressure given Osmotic Coefficient
Go
Verified Osmotic Coefficient given Ideal and Excess Pressure
Go
5 More Osmotic Coefficient and Current Efficiency Calculators
Go
Created Density of Solution given Osmotic Pressure
Go
Created Equilibrium Height given Osmotic Pressure
Go
Created Moles of Solute given Osmotic Pressure
Go
Created Osmotic Pressure for Non Electrolyte
Go
Created Osmotic Pressure given Concentration of Two Substances
Go
Created Osmotic Pressure given Density of Solution
Go
Created Osmotic Pressure given Depression in Freezing Point
Go
Created Osmotic Pressure given Relative Lowering of Vapour Pressure
Go
Created Osmotic Pressure given Vapour Pressure
Go
Created Osmotic Pressure given Volume and Concentration of Two Substances
Go
Created Osmotic Pressure given Volume and Osmotic Pressure of Two Substances
Go
Created Osmotic Pressure using Number of Moles and Volume of Solution
Go
Created Relative Lowering of Vapour Pressure given Osmotic Pressure
Go
Created Temperature of Gas given Osmotic Pressure
Go
Created Total Concentration of Particles using Osmotic Pressure
Go
Created Van't Hoff Factor given Osmotic Pressure
Go
Created Van't Hoff Osmotic Pressure for Electrolyte
Go
Created Van't Hoff Osmotic Pressure for Mixture of Two Solutions
Go
Created Volume of Solution given Osmotic Pressure
Go
Verified Average Specific Pressure Drop Given Top Bed Pressure Drop and Bottom Bed Pressure Drop
Go
Verified Height of Overall Gas Phase Transfer Unit in Packed Column
Go
Verified Log Mean Driving Force Based on Mole Fraction
Go
Verified Number of Transfer Units for Dilute System in Packed Column
Go
12 More Packed Column Designing Calculators
Go
Verified Parachor Given Critical Volume
Go
Verified Parachor given Surface Tension
Go
Created Covalent Ionic Resonance Energy using Pauling's Electronegativity
Go
Created Covalent Radius given Pauling's Electronegativity
Go
Created Effective Nuclear Charge given Pauling's Electronegativity
Go
Created Electron Affinity of element using Pauling's Electronegativity
Go
Created Ionization Energy of Element using Pauling's Electronegativity
Go
Created Pauling's Electronegativity from Allred Rochow's Electronegativity
Go
Created Pauling's Electronegativity from Mulliken's Electronegativity
Go
Created Pauling's Electronegativity given Bond Energies
Go
Created Pauling's Electronegativity given Effective Nuclear Charge and Covalent Radius
Go
Created Pauling's Electronegativity given IE and EA
Go
Created Pauling's Electronegativity given Individual Electronegativities
Go
Created Actual Pressure given Peng Robinson Parameter a, and other Actual and Reduced Parameters
Go
Created Actual Pressure given Peng Robinson Parameter a, and other Reduced and Critical Parameters
Go
Created Actual Pressure given Peng Robinson Parameter b, other Actual and Reduced Parameters
Go
Created Actual Pressure given Peng Robinson Parameter b, other Reduced and Critical Parameters
Go
Created Actual Temperature for Peng Robinson Equation using Alpha-function and Pure Component Parameter
Go
Created Actual Temperature given Peng Robinson Parameter a, and other Actual and Reduced Parameters
Go
Created Actual Temperature given Peng Robinson Parameter a, and other Reduced and Critical Parameters
Go
Created Actual Temperature given Peng Robinson Parameter b, other Actual and Reduced Parameters
Go
Created Actual Temperature given Peng Robinson parameter b, other reduced and critical parameters
Go
Created Alpha-function for Peng Robinson Equation of state given Critical and Actual Temperature
Go
Created Alpha-function for Peng Robinson Equation of state given Reduced Temperature
Go
Created Peng Robinson Alpha-Function using Peng Robinson Equation
Go
Created Peng Robinson Alpha-Function using Peng Robinson Equation given Reduced and Critical Parameters
Go
Created Pressure of Real Gas using Peng Robinson Equation
Go
Created Pressure of Real Gas using Peng Robinson Equation given Reduced and Critical Parameters
Go
Created Pure Component Factor for Peng Robinson Equation of state using Acentric Factor
Go
Created Pure Component Factor for Peng Robinson Equation of state using Critical and Actual Temperature
Go
Created Pure Component Factor for Peng Robinson Equation of state using Reduced Temperature
Go
Created Temperature of Real Gas using Peng Robinson Equation
Go
Created Temperature of Real Gas using Peng Robinson Equation given Reduced and Critical Parameters
Go
Created Peng Robinson Parameter a, of Real Gas given Critical Parameters
Go
Created Peng Robinson parameter a, of Real Gas given Reduced and Actual Parameters
Go
Created Peng Robinson Parameter a, using Peng Robinson Equation
Go
Created Peng Robinson Parameter a, using Peng Robinson Equation given Reduced and Critical Parameters
Go
Created Peng Robinson Parameter b of Real Gas given Critical Parameters
Go
Created Peng Robinson Parameter b of Real Gas given Reduced and Actual Parameters
Go
Verified Bond energy of elements A and B
Go
Verified Crystal Radius
Go
Verified Distance between two metal atoms
Go
Verified Frequency of characteristic X-ray
Go
Verified Ionic Charge of Element
Go
Verified Ionic Radius of Element
Go
Verified Polarizing Power
Go
Verified Wavelength of characteristic X-ray
Go
11 More Periodic Table and Periodicity Calculators
Go
Verified Mobile Phase Travel Time through Column
Go
5 More Phase Calculators
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Verified Kinetic Energy given Threshold Wavelength
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6 More Photo Electric Effect Calculators
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PIB (2)
Created Mass of Each Gas Molecule in 2D Box given Pressure
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Created Number of Gas Molecules in 2D Box given Pressure
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16 More PIB Calculators
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Verified Apparent Tissue Volume given Plasma Volume and Apparent Volume
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Verified Average Concentration of Plasma at Steady State
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Verified Average Plasma Concentration given Peak through Fluctuation
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Verified Fractional Excretion of Sodium
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Verified Initial Concentration for Intravenous Bolus
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Verified Lowest Plasma Concentration Given Peak through Fluctuation
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Verified Peak Plasma Concentration Given Peak through Fluctuation
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Verified Peak through Fluctuation
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Verified Plasma Concentration of Constant Rate Infusion at Steady State
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Verified Plasma Volume of Drug given Apparent Volume
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Verified Renal Clearance using Rate of Reabsorption
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Verified Initial Reactant Concentration for Second Order Reaction using Space Time for Plug Flow
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Verified Initial Reactant Concentration for Zero Order Reaction using Space Time for Plug Flow
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Verified Rate Constant for First Order Reaction using Reactant Concentration for Plug Flow
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Verified Rate Constant for First Order Reaction using Space Time for Plug Flow
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Verified Rate Constant for Second Order Reaction using Reactant Concentration for Plug Flow
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Verified Rate Constant for Second Order Reaction using Space Time for Plug Flow
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Verified Rate Constant for Zero Order Reaction using Space Time for Plug Flow
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Verified Reactant Concentration for Zero Order Reaction using Space Time for Plug Flow
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Verified Reactant Conversion for Zero Order Reaction using Space Time for Plug Flow
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Verified Space Time for First Order Reaction for Plug Flow
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Verified Space Time for First Order Reaction using Reactant Concentration for Plug Flow
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Verified Space Time for Second Order Reaction for Plug Flow
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Verified Space Time for Second Order Reaction using Reactant Concentration for Plug Flow
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Verified Space Time for Zero Order Reaction for Plug Flow
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Verified Initial Reactant Concentration for Second Order Reaction for Plug Flow
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Verified Initial Reactant Concentration for Zero Order Reaction for Plug Flow
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Verified Rate Constant for First Order Reaction for Plug Flow
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Verified Rate Constant for Zero Order Reaction for Plug Flow
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Verified Reactant Conversion for Zero Order Reaction for Plug Flow
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Verified Space Time for First Order Reaction using Rate Constant for Plug Flow
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Verified Space Time for Zero Order Reaction using Rate Constant for Plug Flow
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Verified Space Time for Second Order Reaction using Rate Constant for Plug Flow
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2 More Plug Flow Reactor Calculators
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Verified Area at Point 1 using Pascal's Law
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Verified Area at Point 2 using Pascal's Law
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Verified Barometric Pressure or Atmospheric Pressure
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Verified Force at Point 1 using Pascal's Law
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Verified Force at Point 2 using Pascal's Law
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Verified Gauge Pressure given Absolute Pressure
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Verified Vacuum Pressure given Atmospheric Pressure
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1 More Pressure and its Measurement Calculators
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Created Pressure of Real Gas using Clausius Equation
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Created Pressure of Real Gas using Clausius Equation given Reduced and Critical Parameters
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Created Temperature of Real Gas using Clausius Equation
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Created Temperature of Real Gas using Clausius Equation given Reduced and Critical Parameters
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Created Pressure of Gas given Average Velocity and Density in 2D
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Created Pressure of Gas given Average Velocity and Volume in 2D
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Created Pressure of Gas given most probable Speed and Density in 2D
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Created Pressure of Gas given Most Probable Speed and Volume in 2D
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Created Pressure of Gas given Root Mean Square Speed and Density in 1D
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Created Pressure of Gas given Root Mean Square Speed and Density in 2D
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Created Pressure of Gas given Root Mean Square Speed and Volume in 1D
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Created Pressure of Gas given Root Mean Square Speed and Volume in 2D
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Created Pressure of Gas Molecules in 1D Box
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Created Pressure of Gas Molecules in 2D Box
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10 More Pressure of Gas Calculators
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Verified Time Constant for Heating Process
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Verified Time Constant for Mercury in Glass Thermometer
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Verified Time Constant for Mixing Process
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Verified Time Period of Oscillations using Time Constant and Damping Factor
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Verified Transportation Lag
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Verified Equilibrium Constant for Reverse Reaction
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Verified Equilibrium Constant with respect to Mole Fraction
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Verified Equilibrium Constant with respect to Partial Pressure
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Verified Equilibrium Mole Fraction of Substance A
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Verified Equilibrium Mole Fraction of Substance B
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Verified Equilibrium Mole Fraction of Substance C
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Verified Equilibrium Mole Fraction of Substance D
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Verified Equilibrium Partial Pressure of Substance A
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Verified Equilibrium Partial Pressure of Substance B
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Verified Equilibrium Partial Pressure of Substance C
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Verified Equilibrium Partial Pressure of Substance D
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Verified Molar Concentration of Substance A
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Verified Molar Concentration of Substance B
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Verified Molar Concentration of Substance C
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Verified Molar Concentration of Substance D
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Verified Reaction Quotient
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5 More Properties of Equilibrium Constant Calculators
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Verified Angular Velocity given Revolution Per Unit Time
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Verified Coefficient of Volume Expansion for Ideal Gas
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Verified Density of Fluid
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Verified Enthalpy given Flow Work
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Verified Enthalpy given Specific Volume
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Verified Flow Work given Density
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Verified Flow Work given Specific Volume
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Verified Height of Capillary Rise in Capillary Tube
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Verified Mach Number of Compressible Fluid Flow
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Verified Relative Density of Fluid
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Verified Shear Force given Shear Stress
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Verified Shear Stress Acting on Fluid Layer
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Verified Specific Gravity of Fluid given Density of Water
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Verified Specific Total Energy
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Verified Specific Volume given Density
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Verified Specific Volume of Fluid given Mass
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Verified Specific Weight of Substance
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Verified Tangential Velocity given Angular Velocity
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Verified Torque on Cylinder given Angular Velocity and Radius of Inner Cylinder
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Verified Torque on Cylinder given Radius, Length and Viscosity
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Verified Volume Expansivity for Ideal Gas
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Verified Weight Density given Density
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Verified Weight of Liquid Column in Capillary Tube
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Verified Wetted Surface Area
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2 More Properties of Fluids Calculators
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Verified Diffuse Radiation Exchange from Surface 1 to Surface 2
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Verified Diffuse Radiation Exchange from Surface 2 to Surface 1
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Verified Diffuse Radiosity
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Verified Direct Diffuse Radiation from Surface 2 to Surface 1
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Verified Net Heat Lost by Surface
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Verified Net Heat Lost by Surface given Diffuse Radiosity
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Verified Reflectivity given Specular and Diffuse Component
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Verified Transmissivity given Specular and Diffuse Component
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Verified Absorptivity given Reflectivity and Transmissivity
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Verified Area of Surface 1 given Area 2 and Radiation Shape Factor for Both Surfaces
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Verified Area of Surface 2 given Area 1 and Radiation Shape Factor for Both Surfaces
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Verified Emissive Power of Blackbody
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Verified Emissive Power of Non Blackbody given Emissivity
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Verified Emissivity of Body
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Verified Energy of each Quanta
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Verified Frequency given Speed of Light and Wavelength
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Verified Mass of Particle Given Frequency and Speed of Light
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Verified Maximum Wavelength at given Temperature
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Verified Net Energy Leaving given Radiosity and Irradiation
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Verified Radiation Temperature given Maximum Wavelength
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Verified Radiosity given Emissive Power and Irradiation
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Verified Reflected Radiation given Absorptivity and Transmissivity
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Verified Reflectivity given Absorptivity for Blackbody
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Verified Reflectivity given Emissivity for Blackbody
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Verified Resistance in Radiation Heat Transfer when No Shield is Present and Equal Emissivities
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Verified Shape Factor 12 given Area of Both Surface and Shape Factor 21
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Verified Shape Factor 21 given Area of Both Surface and Shape Factor 12
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Verified Temperature of Radiation Shield Placed between Two Parallel Infinite Planes with Equal Emissivities
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Verified Total Resistance in Radiation Heat Transfer given Emissivity and Number of Shields
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Verified Transmissivity Given Reflectivity and Absorptivity
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Verified Wavelength Given Speed of Light and Frequency
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Verified Heat Transfer between Concentric Spheres
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Verified Heat Transfer between Small Convex Object in Large Enclosure
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Verified Heat Transfer between Two Infinite Parallel Planes given Temp and Emissivity of Both Surfaces
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Verified Heat Transfer between Two Long Concentric Cylinder given Temp, Emissivity and Area of Both Surfaces
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Verified Net Heat Exchange between Two Surfaces given Radiosity for Both Surface
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Verified Net Heat Exchange given Area 1 and Shape Factor 12
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Verified Net Heat Exchange given Area 2 and Shape Factor 21
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Verified Net Heat Transfer from Surface given Emissivity, Radiosity and Emissive Power
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Verified Radiation Heat Transfer between Plane 1 and Shield given Temperature and Emissivity of Both Surfaces
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Verified Radiation Heat Transfer between Plane 2 and Radiation Shield given Temperature and Emissivity
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Verified Emissive Power of Blackbody through Medium
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Verified Emissive Power of Blackbody through Medium given Emissivity of Medium
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Verified Emissivity of Medium given Emissive Power of Blackbody through Medium
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Verified Energy Emitted by Medium
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Verified Energy Leaving Surface 1 that is Transmitted through Medium
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Verified Net Heat Exchange in Transmission Process
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Verified Temperature of Medium given Emissive Power of Blackbody
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Verified Transmissivity of Transparent Medium given Radiosity and Shape Factor
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Verified Catalytic Rate Constant at Low Substrate Concentration
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Verified Catalytic Rate Constant given Dissociation Rate Constant
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Verified Catalytic Rate Constant given Reverse and Forward Rate Constant
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Verified Dissociation Rate Constant given Catalytic Rate Constant
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Verified Dissociation Rate Constant given Concentration of Enzyme and Substrate
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Verified Dissociation Rate Constant in Enzymatic Reaction Mechanism
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Verified Forward Rate Constant given Dissociation Rate Constant
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Verified Forward Rate Constant given Reverse and Catalytic Rate Constant
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Verified Forward Rate Constant in Enzymatic Reaction mechanism
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Verified Rate Constant given Initial Rate and Enzyme Substrate Complex Concentration
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Verified Rate Constant given Maximum Rate and Initial Enzyme Concentration
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Verified Reverse Rate Constant given Dissociation Rate Constant
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Verified Reverse Rate Constant given Forward and Catalytic Rate Constants
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Verified Reverse Rate Constant given Michaelis Constant
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Verified Reverse Rate Constant in Enzymatic Reaction Mechanism
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1 More Rate Constants of Enzymatic Reaction Calculators
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Verified Bound Moisture Content based on Weight of Bound Moisture
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Verified Critical Moisture Content based on Weight of Critical Moisture
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Verified Dry Weight of Solid based on Bound Moisture Content
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Verified Dry Weight of Solid based on Critical Moisture Content
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Verified Dry Weight of Solid based on Equilibrium Moisture Content
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Verified Dry Weight of Solid based on Free Moisture Content
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Verified Dry Weight of Solid based on Initial Moisture Content
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Verified Dry Weight of Solid based on Unbound Moisture Content
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Verified Equilibrium Moisture Content based on Weight of Equilibrium Moisture
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Verified Free Moisture Content based on Weight of Free Moisture
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Verified Initial Moisture Content based on Weight of Initial Moisture
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Verified Unbound Moisture Content based on Weight of Unbound Moisture
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Verified Weight of Bound Moisture based on Bound Moisture Content
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Verified Weight of Critical Moisture based on Critical Moisture Content
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Verified Weight of Equilibrium Moisture based on Equilibrium Moisture Content
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Verified Weight of Free Moisture based on Free Moisture Content
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Verified Weight of Initial Moisture based on Initial Moisture Content
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Verified Weight of Unbound Moisture based on Unbound Moisture Content
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Verified Number of Moles Formed using Reaction Rate of Reacting Fluid
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Verified Reacting Fluid Volume using Reaction Rate
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Verified Reaction Rate based on Volume of Reacting Fluid
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Verified Reaction Time Interval of Reacting Fluid using Reaction Rate
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Verified Number of Moles Formed using Reaction Rate of Reactor
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Verified Reaction Rate in Reactor
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Verified Reaction Time Interval of Reactor using Reaction Rate
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Verified Reactor Volume using Reaction Rate
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Verified Rate Constant for Second Order Reaction for Plug Flow
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16 More Reactor Performance Equations for Variable Volume Reactions Calculators
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Verified Final Reactant Conversion
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Verified Fresh Molar Feed Rate
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Verified Rate Constant for First Order Reaction using Recycle Ratio
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Verified Rate Constant for Second Order Reaction using Recycle Ratio
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Verified Recycle Ratio
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Verified Recycle Ratio using Reactant Conversion
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Verified Recycle Ratio using Total Feed Rate
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Verified Space Time for First Order Reaction using Recycle Ratio
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Verified Space Time for Second Order Reaction using Recycle Ratio
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Verified Total Feed Reactant Conversion
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Verified Total Molar Feed Rate
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Verified Volume leaving System
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Verified Volume of Fluid returned to Reactor Entrance
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Created Actual Molar Volume of Real Gas using Reduced Redlich Kwong Equation
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Created Actual Molar Volume using Redlich Kwong Equation given 'a' and 'b'
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Created Actual Pressure of Real Gas using Redlich Kwong Equation given 'b'
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Created Actual Pressure of Real Gas using Reduced Redlich Kwong Equation
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Created Actual Pressure using Redlich Kwong Equation given 'a' and 'b'
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Created Actual Temperature of Real Gas using Redlich Kwong Equation given 'a'
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Created Actual Temperature of Real Gas using Redlich Kwong Equation given 'b'
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Created Actual Temperature of Real Gas using Reduced Redlich Kwong Equation
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Created Actual Temperature using Redlich Kwong Equation given 'a' and 'b'
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Created Critical Molar Volume of Real Gas using Redlich Kwong Equation given 'a' and 'b'
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Created Critical Molar Volume of Real Gas using Reduced Redlich Kwong Equation
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Created Critical Pressure of Real Gas using Redlich Kwong Equation given 'a'
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Created Critical Pressure of Real Gas using Redlich Kwong Equation given 'a' and 'b'
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Created Critical Pressure of Real Gas using Redlich Kwong Equation given 'b'
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Created Critical Pressure of Real Gas using Reduced Redlich Kwong Equation
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Created Molar Volume of Real Gas using Redlich Kwong Equation
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Created Pressure of Real Gas using Redlich Kwong Equation
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Created Reduced Molar Volume of Real Gas using Reduced Redlich Kwong Equation
Go
Created Reduced Molar Volume using Redlich Kwong Equation given 'a' and 'b'
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Created Reduced Pressure of Real Gas using Redlich Kwong Equation given 'a'
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Created Reduced Pressure of Real Gas using Redlich Kwong Equation given 'b'
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Created Reduced Pressure of Real Gas using Reduced Redlich Kwong Equation
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Created Reduced Pressure using Redlich Kwong Equation given 'a' and 'b'
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Created Redlich Kwong Parameter a, given Reduced and Actual Pressure
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Created Redlich Kwong Parameter at Critical Point
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Created Redlich Kwong Parameter b at Critical Point
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Created Redlich Kwong Parameter b given Pressure, Temperature and Molar Volume of Real Gas
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Created Redlich Kwong Parameter b given Reduced and Actual Pressure
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Created Redlich Kwong Parameter given Pressure, Temperature and Molar Volume of Real Gas
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Created Reduced Molar Volume of Real Gas given Wohl Parameter a, and Actual and Critical Parameters
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Created Reduced Molar Volume of Real Gas given Wohl Parameter a, and Actual and Reduced Parameters
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Created Reduced Molar Volume of Real Gas given Wohl Parameter b and Actual and Critical Parameters
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Created Reduced Molar Volume of Real Gas given Wohl Parameter b and Actual and Reduced Parameters
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Created Reduced Molar Volume of Real Gas given Wohl Parameter c and Actual and Critical Parameters
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Created Reduced Molar Volume of Real Gas given Wohl Parameter c and Actual and Reduced Parameters
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Created Reduced Molar Volume of Real Gas using Actual and Critical Volume
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Created Reduced Molar Volume of Wohl's Real Gas given other Actual and Critical Parameters
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Created Reduced Molar Volume of Wohl's Real Gas given other Actual and Reduced Parameters
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Created Reduced Pressure given Peng Robinson Parameter a, and other Actual and Critical Parameters
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Created Reduced Pressure given Peng Robinson Parameter a, and other Actual and Reduced Parameters
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Created Reduced Pressure given Peng Robinson Parameter b, other Actual and Critical Parameters
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Created Reduced Pressure given Peng Robinson Parameter b, other Actual and Reduced Parameters
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Created Reduced Pressure using Peng Robinson Equation given Critical and Actual Parameters
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Created Reduced Pressure using Peng Robinson Equation given Reduced and Critical Parameters
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Created Reduced Pressure of Real Gas given Clausius Parameter a, Reduced and Actual Parameters
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Created Reduced Pressure of Real Gas given Clausius Parameter and Actual Parameters
Go
Created Reduced Pressure of Real Gas given Clausius Parameter b and Actual Parameters
Go
Created Reduced Pressure of Real Gas given Clausius Parameter b, Reduced and Actual Parameters
Go
Created Reduced Pressure of Real Gas given Clausius Parameter c and Actual Parameters
Go
Created Reduced Pressure of Real Gas given Clausius Parameter c, Reduced and Actual Parameters
Go
Created Reduced Pressure of Real Gas using Actual and Critical Pressure
Go
Created Reduced Pressure of Real Gas using Clausius Equation given Critical and Actual Parameters
Go
Created Reduced Pressure of Real Gas using Clausius Equation given Reduced and Actual Parameters
Go
Created Reduced Pressure of Real Gas using Clausius Equation given Reduced and Critical Parameters
Go
Created Reduced Temperature for Peng Robinson Equation using Alpha-function and Pure Component Parameter
Go
Created Reduced Temperature given Peng Robinson Parameter a, and other Actual and Critical Parameters
Go
Created Reduced Temperature given Peng Robinson Parameter a, and other Actual and Reduced Parameters
Go
Created Reduced Temperature given Peng Robinson Parameter b, other Actual and Critical Parameters
Go
Created Reduced Temperature given Peng Robinson Parameter b, other Actual and Reduced Parameters
Go
Created Reduced Temperature using Peng Robinson Equation given Critical and Actual Parameters
Go
Created Reduced Temperature using Peng Robinson Equation given Reduced and Critical Parameters
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Created Reduced Temperature of Real Gas given Clausius Parameter a, Reduced and Actual Parameters
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Created Reduced Temperature of Real Gas given Clausius Parameter and Actual Parameters
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Created Reduced Temperature of Real Gas given Clausius Parameter c and Actual Parameters
Go
Created Reduced Temperature of Real Gas given Clausius Parameter c given Reduced and Actual Parameters
Go
Created Reduced Temperature of Real Gas using Clausius Equation given Critical and Actual Parameters
Go
Created Reduced Temperature of Real Gas using Clausius Equation given Reduced and Actual Parameters
Go
Created Reduced Temperature of Real Gas using Clausius Equation given Reduced and Critical Parameters
Go
Created Reduced Temperature of Real Gas using Clausius Parameter b and Actual Parameters
Go
Created Reduced Temperature of Real Gas using Clausius Parameter b given Reduced and Actual Parameters
Go
Created Reduced Temperature of Real Gas given Wohl Parameter a, Actual and Critical Parameters
Go
Created Reduced Temperature of Real Gas given Wohl Parameter a. and Actual and Reduced Parameters
Go
Created Reduced Temperature of Real Gas given Wohl Parameter b and Actual and Critical Parameters
Go
Created Reduced Temperature of Real Gas given Wohl Parameter b and Actual and Reduced Parameters
Go
Created Reduced Temperature of Real Gas given Wohl Parameter c and Actual and Critical Parameters
Go
Created Reduced Temperature of Real Gas given Wohl Parameter c and Actual and Reduced Parameters
Go
Created Reduced Temperature of Real Gas using Wohl Equation given Reduced and Critical Parameters
Go
Created Reduced Temperature of Real Gas using Wohl Equation using Critical and Actual Parameters
Go
Created Reduced Temperature of Wohl's Real Gas given other Actual and Critical Parameters
Go
Created Reduced Temperature of Wohl's Real Gas given other Actual and Reduced Parameters
Go
Created Reduced Molar Volume of Real Gas using Clausius Equation given Critical and Actual Parameters
Go
Created Reduced Molar Volume of Real Gas using Clausius Equation given Reduced and Actual Parameters
Go
Created Reduced Molar Volume of Real Gas using Clausius Equation given Reduced and Critical Parameters
Go
Created Reduced Volume of Real Gas given Clausius Parameter b and Actual Parameters
Go
Created Reduced Volume of Real Gas given Clausius Parameter b, Reduced and Actual Parameters
Go
Created Reduced Volume of Real Gas given Clausius Parameter c and Actual Parameters
Go
Created Reduced Volume of Real Gas given Clausius Parameter c, Reduced and Actual Parameters
Go
Created Reduced Volume of Real Gas using Actual and Critical Volume
Go
Verified Equilibrium Constant in Terms of Mole Fraction given Degree of Dissociation
Go
19 More Relation between Equilibrium Constant and Degree of Dissociation Calculators
Go
Verified Initial Vapour Density using Concentration of Reaction
Go
Verified Initial Vapour Density when Number of Moles of Products at Equilibrium is Half
Go
Verified Molecular Weight abnormal given Vapour Density at Equilibrium
Go
Verified Volume of Equilibrium Mixture of Substances A and B
Go
20 More Relation between Vapour Density and Degree of Dissociation Calculators
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Verified Partition Coefficient of Solute 1 given Relative Retention
Go
Verified Partition Coefficient of Solute 2 given Relative Retention
Go
Verified Relative Retention given Capacity Factor of Two Components
Go
Verified Relative Retention given Partition Coefficient of Two Components
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3 More Relative and Adjusted Retention Calculators
Go
Created Molality using Relative Lowering of Vapour Pressure
Go
Created Mole Fraction of Solute given Vapour Pressure
Go
Created Mole Fraction of Solvent given Vapour Pressure
Go
Created Molecular Mass of Solute given Relative Lowering of Vapour Pressure
Go
Created Molecular Mass of Solvent given Relative Lowering of Vapour Pressure
Go
Created Moles of Solute in Dilute Solution given Relative Lowering of Vapour Pressure
Go
Created Moles of Solvent in Dilute Solution given Relative Lowering of Vapour Pressure
Go
Created Ostwald-Walker Dynamic Method for Relative Lowering of Vapour Pressure
Go
Created Relative Lowering of Vapour Pressure
Go
Created Relative Lowering of Vapour Pressure given Molecular Mass and Molality
Go
Created Relative Lowering of Vapour Pressure given Number of Moles for Concentrated Solution
Go
Created Relative Lowering of Vapour Pressure given Number of Moles for Dilute Solution
Go
Created Relative Lowering of Vapour Pressure given Weight and Molecular Mass of Solute and Solvent
Go
Created Van't Hoff Factor for Relative Lowering of Vapour Pressure given Molecular Mass and Molality
Go
Created Van't Hoff Factor for Relative Lowering of Vapour Pressure using Number of Moles
Go
Created Van't Hoff Relative Lowering of Vapour Pressure given Molecular Mass and Molality
Go
Created Van't Hoff Relative Lowering of Vapour Pressure given Number of Moles
Go
Created Weight of Solute given Relative Lowering of Vapour Pressure
Go
Created Weight of Solvent given Relative Lowering of Vapour Pressure
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2 More Relative Lowering of Vapour Pressure Calculators
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Verified Relative Volatility using Vapour Pressure
Go
9 More Relative Volatility and Vaporization Ratio Calculators
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Verified Distance between Electrode given Resistance and Resistivity
Go
Verified Electrode Cross-Section Area given Resistance and Resistivity
Go
Verified Resistance given Conductance
Go
Verified Resistance given Distance between Electrode and Area of Cross-Section of Electrode
Go
Verified Resistivity given Specific Conductance
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4 More Resistance and Resistivity Calculators
Go
Verified Resolution given Number of Theoretical Plates and Separation Factor
Go
Verified Resolution of Two Peaks given Change in Retention Time
Go
Verified Resolution of Two Peaks given Change in Retention Volume
Go
Verified Resolution of Two Peaks given Half of Average Width of Peaks
Go
Verified Adjusted Retention Time given Retention Time
Go
Verified Average Width of Peak given Resolution and Change in Retention Time
Go
Verified Half Width of Peak given Number of Theoretical Plates and Retention Time
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Verified Retention Time given Adjusted Retention Time
Go
Verified Retention Time given Number of Theoretical Plate and Half Width of Peak
Go
Verified Retention Time given Number of Theoretical Plates and Standard Deviation
Go
Verified Retention Time given Number of Theoretical Plates and Width of Peak
Go
Verified Retention Time given Retention Volume
Go
Verified Width of Peak given Number of Theoretical Plates and Retention Time
Go
1 More Retention Time Calculators
Go
Verified Average Width of Peak given Resolution and Change in Retention Volume
Go
Verified Flow Rate given Retention Volume and Time
Go
Verified Half of Average Width of Peaks given Resolution and Change in Retention Volume
Go
Verified Retention Factor
Go
Verified Retention Volume given Capacity Factor
Go
Verified Retention Volume given Flow Rate
Go
Verified Unretained Volume given Capacity Factor
Go
Created RMS Velocity given Average Velocity in 2D
Go
Created RMS Velocity given Most Probable Velocity in 2D
Go
Created RMS Velocity given Pressure and Density in 1D
Go
Created RMS Velocity given Pressure and Density in 2D
Go
Created RMS Velocity given Pressure and Volume of Gas in 1D
Go
Created RMS Velocity given Pressure and Volume of Gas in 2D
Go
Created RMS Velocity given Temperature and Molar Mass in 1D
Go
Created RMS Velocity given Temperature and Molar Mass in 2D
Go
5 More RMS Velocity Calculators
Go
Verified Bending Moment at Centre of Vessel Span
Go
Verified Bending Moment at Support
Go
Verified Combined Stresses at Bottommost Fibre of Cross Section
Go
Verified Combined Stresses at Mid Span
Go
Verified Combined Stresses at Topmost Fibre of Cross Section
Go
Verified Corresponding Bending Stress with Section Modulus
Go
Verified Stability Coefficient of Vessel
Go
Verified Stress due to Longitudinal Bending at Bottom most Fibre of Cross Section
Go
Verified Stress due to Longitudinal Bending at Mid-Span
Go
Verified Stress due to Longitudinal Bending at Top most Fibre of Cross Section
Go
Verified Stress due to Seismic Bending Moment
Go
1 More Saddle Support Calculators
Go
Created Critical Saturation Vapor Pressure using Acentric Factor
Go
Created Critical Saturation Vapor Pressure using Actual and Reduced Saturation Vapor Pressure
Go
Created Reduced Saturation Vapor Pressure using Acentric Factor
Go
Created Reduced Saturation Vapor Pressure using Actual and Critical Saturation Vapor Pressure
Go
Created Saturation Vapor Pressure using Acentric Factor
Go
Created Saturation Vapor Pressure using Reduced and Critical Saturation Vapor Pressure
Go
2 More Saturation Vapour Pressure Calculators
Go
Verified Electric Part of Helmholtz Free Entropy given Classical Part
Go
Verified Helmholtz Free Entropy given Classical and Electric Part
Go
Verified Internal Energy given Helmholtz Free Entropy and Entropy
Go
Verified Pressure given Gibbs and Helmholtz Free Entropy
Go
13 More Second Laws of Thermodynamics Calculators
Go
Verified Rate Constant of Second Order Irreversible Reaction
Go
Verified Reactant Concentration of Second Order Irreversible Reaction
Go
Verified Reaction Rate of Second Order Irreversible Reaction
Go
3 More Second Order Irreversible Reaction Calculators
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Verified Allowable Crushing Strength of Bolt
Go
Verified Allowable Shear Strength of Bolt
Go
Verified Allowable Shear Strength of Coupling Material
Go
Verified Maximum Torque for Crushing Failure of Bolt
Go
Verified Maximum Torque for Shear Failure of Bolt
Go
Verified Maximum Torque Transmission Capacity of Coupling
Go
Verified Maximum Torque Transmission Capacity of Coupling under Bearing Pressure
Go
Verified Torque Transmission Capacity for Torsional Failure of Hub
Go
7 More Shaft Couplings Calculators
Go
Verified Allowable Shear Strength of Flange
Go
Verified Torque Transmission Capacity for Shear Failure of Flange
Go
Verified Bending Stress given Normal Stress
Go
15 More Shaft Design on Strength Basis Calculators
Go
Verified Bending Stress for Hollow Shaft
Go
Verified Bending Stress for Solid Shaft
Go
Verified Maximum Torque of Shaft Subjected to Bending Moment only
Go
4 More Shaft Subjected to Bending Moment Only Calculators
Go
Verified Compressive Stress between Bearing Plate and Concrete Foundation
Go
Verified Maximum Bending Moment at Junction of Skirt and Bearing Plate
Go
Verified Minimum Stress between Bearing Plate and Concrete Foundation
Go
4 More Skirt Supports Calculators
Go
Created Adiabatic Index of Real Gas
Go
Created Adiabatic Index of Real Gas given Heat Capacity at Constant Pressure
Go
Created Adiabatic Index of Real Gas given Heat Capacity at Constant Volume
Go
Created Coefficient of Thermal Expansion of Real Gas
Go
Created Coefficient of Thermal Expansion of Real Gas given Difference between Cp and Cv
Go
Created Difference between Cp and Cv of Real Gas
Go
Created Heat Capacity at Constant Pressure of Real Gas
Go
Created Heat Capacity at Constant Volume of Real Gas
Go
Created Isothermal Compressibility of Real Gas
Go
Created Isothermal Compressibility of Real Gas given Difference between Cp and Cv
Go
Created Specific Volume of Real Gas given Difference between Cp and Cv
Go
Created Specific Volume of Real Gas given Heat Capacities
Go
Created Temperature of Real Gas given Difference between Cp and Cv
Go
Created Temperature of Real Gas given Heat Capacities
Go
Verified Change in Surface Potential
Go
Verified Specific Surface Area
Go
Verified Specific Surface Area for array of n Cylindrical Particles
Go
Verified Specific Surface Area for Flat Disk
Go
Verified Specific Surface Area for Thin Rod
Go
Verified Surface Enthalpy given Critical Temperature
Go
Verified Surface Entropy given Critical Temperature
Go
Verified Surface Viscosity
Go
Created Surface Area of One Particle given Sphericity
Go
4 More Sphericity of Particles Calculators
Go
Verified Standard Deviation given Retention Time and Number of Theoretical Plates
Go
3 More Standard Deviation Calculators
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Verified Intensity of Incident Light
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Verified Intensity of Light Absorbed
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Verified Intensity of Transmitted Light
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Verified Number of Molecules of Product formed in 1 second
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Verified Number of Molecules of Reactant consumed in 1 second
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Verified Number of Quanta absorbed in 1 second using Quantum Efficiency of Reactant
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Verified Quantum Efficiency for Disappearance of Reactant
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Verified Quantum Efficiency for Formation of Product
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10 More Stark Einstein law Calculators
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Verified Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles
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Verified Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles at Equilibrium
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Verified Moles of Volatile component Volatilized from mixture of Non-Volatiles by Steam
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Verified Moles of Volatile component Volatilized from mixture of Non-Volatiles by Steam at Equilibrium
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Verified Total Steam Required to Vaporize Volatile Component
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Created Enthalpy Change in Melting
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Created Entropy Change in Melting
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Created Free Volume in Polymer System
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Created Melting Temperature of Polymer
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Created Total Volume of Polymer Sample
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Created Volume Occupied by Polymer
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8 More Step Wise Polymerization Calculators
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Verified Percent Yield of Chemical Reaction
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Verified Stoichiometric Number given Change in Number of Moles and Extent of Reaction
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Verified Stoichiometric Number given Number of Moles Initially and at Equilibrium
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2 More Stoichiometry Calculators
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Verified Bragg Equation for Distance between Planes of Atoms in Crystal Lattice
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Verified Bragg Equation for Order of Diffraction of Atoms in Crystal Lattice
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Verified Bragg equation for Wavelength of Atoms in Crystal Lattice
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27 More Structure of Atom Calculators
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Verified Surface Pressure
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Verified Surface Pressure for Ideal Gas Film
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1 More Surface Pressure Calculators
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Verified Gibbs Free Energy Given Surface Area
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Verified Height of Magnitude of Capillary Rise
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Verified Surface Tension for very Thin Plate using Wilhelmy-Plate Method
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Verified Surface Tension Force given Density of Fluid
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Verified Surface Tension given Contact Angle
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Verified Surface Tension given Correction Factor
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Verified Surface Tension given Critical Temperature
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Verified Surface Tension Given Density of Vapor
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Verified Surface Tension Given Force
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Verified Surface Tension Given Gibbs Free Energy
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Verified Surface Tension Given Maximum Volume
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Verified Surface Tension given Molar Volume
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Verified Surface Tension given Molecular Weight
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Verified Surface Tension given Temperature
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Verified Surface Tension of Liquid Methane
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Verified Surface Tension of Methane+Hexane System
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Verified Surface Tension of Pure Water
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Verified Surface Tension of Sea Water
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Verified Work of Cohesion given Surface Tension
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1 More Surface Tension Calculators
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Verified Charge Transfer Coefficient given Tafel Slope
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Verified Charge Transfer Coefficient given Thermal Voltage
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Verified Current Density for Anodic Reaction from Tafel Equation
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Verified Current Density for Cathodic Reaction from Tafel Equation
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Verified Electric Elementary Charge given Tafel Slope
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Verified Electric Elementary Charge given Thermal Voltage
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Verified Exchange Current Density for Anodic Reaction from Tafel Equation
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Verified Exchange Current Density for Cathodic Reaction from Tafel Equation
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Verified Overpotential for Anodic Reaction from Tafel Equation
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Verified Overpotential for Cathodic Reaction from Tafel Equation
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Verified Tafel Slope for Anodic Reaction from Tafel Equation
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Verified Tafel Slope for Cathodic Reaction from Tafel Equation
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Verified Tafel Slope given Temperature and Charge Transfer Coefficient
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Verified Tafel Slope given Thermal Voltage
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Verified Thermal Voltage given Tafel Slope
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Verified Thermal Voltage given Temperature and Electric Elementary Charge
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Verified Critical Chain Length of Hydrocarbon Tail using Tanford Equation
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Verified Number of Carbon Atoms given Critical Chain Length of Hydrocarbon
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Verified Number of Carbon Atoms given Volume of Hydrocarbon chain
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Verified Volume of Hydrocarbon Chain using Tanford Equation
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Created Temperature given Average Thermal Energy of Linear Polyatomic Gas Molecule
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Created Temperature given Average Thermal Energy of Non-Linear Polyatomic Gas Molecule
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Created Temperature given Internal Molar Energy of Linear Molecule
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Created Temperature given Internal Molar Energy of Non-Linear Molecule
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Created Temperature given Molar Vibrational Energy of Linear Molecule
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Created Temperature given Molar Vibrational Energy of Non-Linear Molecule
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Created Temperature given Vibrational Energy of Linear Molecule
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Created Temperature given Vibrational Energy of Non-Linear Molecule
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Verified Adiabatic Heat of Equilibrium Conversion
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Verified Final Temperature for Equilibrium Conversion
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Verified Heat of Reaction at Equilibrium Conversion
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Verified Non Adiabatic Heat of Equilibrium Conversion
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Verified Reactant Conversion at Adiabatic Conditions
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Verified Reactant Conversion at Non Adiabatic Conditions
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3 More Temperature and Pressure Effects Calculators
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Created Pressure of Real Gas using Wohl Equation
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Created Pressure of Real Gas using Wohl Equation given Reduced and Critical Parameters
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Created Temperature of Real Gas using Wohl Equation
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Created Temperature of Real Gas using Wohl Equation given Reduced and Critical Parameters
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Verified Temperature given Gibbs and Helmholtz free entropy
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Verified Temperature given Gibbs free energy and Gibbs free entropy
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Verified Temperature given Gibbs free entropy
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Verified Temperature given Helmholtz free energy and Helmholtz free entropy
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Verified Temperature given internal energy and Helmholtz free entropy
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Verified Temperature given Tafel Slope
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Verified Temperature given Thermal Voltage and Electric Elementary Charge
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Verified Temperature of Concentration Cell with Transference given Activities
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Verified Temperature of Concentration Cell with Transference given Transport Number of Anion
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Verified Temperature of concentration cell with transference given valencies
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Verified Temperature of concentration cell without transference for dilute solution given concentration
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Verified Temperature of Concentration Cell without Transference given Activities
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Verified Temperature of concentration cell without transference given concentration and fugacity
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Verified Temperature of Concentration Cell without Transference given Molalities
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Created Temperature given Most Probable Speed and Molar Mass in 2D
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Created Temperature of Gas given Average Velocity in 2D
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Created Temperature of Gas given Root Mean Square Speed and Molar Mass in 1D
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Created Temperature of Gas given Root Mean Square Speed and Molar Mass in 2D
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Verified Temperature of One Gas Molecule given Boltzmann Constant
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7 More Temperature of Gas Calculators
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Verified Inner Heat Transfer Coefficient given Inner Thermal Resistance
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Verified Inside Area given Thermal Resistance for Inner Surface
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Verified Outside Area given Outer Thermal Resistance
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Verified Outside Heat Transfer Coefficient given Thermal Resistance
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4 More Thermal Resistance Calculators
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Verified Amount of Heat Released in Bomb Calorimetry
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Verified Amount of Heat released in Constant-Volume Calorimetry
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Verified Change in Temperature in Calorimetry
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Verified Heat Transfer in Thermochemical Reaction
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Verified Specific Heat Capacity in Thermochemical Equation
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4 More Thermochemistry Calculators
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Verified Equilibrium Constant 1 in Temperature Range T1 and T2
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Verified Equilibrium Constant 2 in Temperature Range T1 and T2
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Verified Equilibrium Constant at Equilibrium
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Verified Equilibrium Constant at Equilibrium given Gibbs Energy
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Verified Equilibrium Constant at Final Temperature T2
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Verified Equilibrium Constant at Initial Temperature T1
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Verified Standard Enthalpy at Final Temperature T2
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Verified Standard Enthalpy at Initial Temperature T1
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Verified Standard Enthalpy of Reaction at Equilibrium
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Verified Standard Entropy Change at Equilibrium
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Verified Standard Entropy Change at Final Temperature T2
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Verified Standard Entropy Change at Initial Temperature T1
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13 More Thermodynamics in Chemical Equilibrium Calculators
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Verified Transport Number of Anion for Concentration Cell with Transference
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Verified Transport Number of Cation for Concentration Cell with Transference
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2 More Transport Number Calculators
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Created Degrees of Freedom of Two Component System
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Created Number of Phases of Two Component System
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Verified Enzyme Substate complex Concentration given Forward, Reverse, and Catalytic Rate Constant
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Verified Enzyme Substrate complex Concentration in Presence of Uncompetitive Inhibitor
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Verified Enzyme Substrate Dissociation constant given Enzyme Substrate Modifying factor
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Verified Enzyme Substrate Dissociation constant in Presence of Uncompetitive Inhibitor
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Verified Enzyme Substrate Inhibitor Concentration in presence of Uncompetitive Inhibitor
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Verified Enzyme Substrate Modifying Factor given Enzyme Substrate Dissociation Constant
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Verified Enzyme Substrate Modifying Factor in Presence of Uncompetitive Inhibitor
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Verified Inhibitor Concentration in Presence of Uncompetitive Inhibitor
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Verified Initial Reaction Rate in presence of Uncompetitive Inhibitor
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Verified Maximum Reaction Rate in Presence of Uncompetitive Inhibitor
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Verified Michaelis Constant in Presence of Uncompetitive Inhibitor
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Verified Substrate Concentration in presence of Uncompetitive Inhibitor
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Verified Biot Number given Characteristic Dimension and Fourier Number
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Verified Biot Number given Heat Transfer Coefficient and Time Constant
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Verified Capacitance of Thermal System by Lumped Heat Capacity Method
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Verified Fourier Number
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Verified Fourier Number given Characteristic Dimension and Biot Number
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Verified Fourier Number given Heat Transfer Coefficient and Time Constant
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Verified Fourier Number using Thermal Conductivity
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Verified Initial Internal Energy Content of Body in Reference to Environment Temperature
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Verified Initial Temperature of Body by Lumped Heat Capacity Method
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Verified Temperature of Body by Lumped Heat Capacity Method
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Verified Temperature Response of Instantaneous Energy Pulse in Semi Infinite Solid
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Verified Temperature Response of Instantaneous Energy Pulse in Semi Infinite Solid at Surface
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Verified Thermal Conductivity given Biot Number
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Verified Time Constant of Thermal System
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Verified Time Taken by Object for Heating or Cooling by Lumped Heat Capacity Method
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3 More Unsteady State Heat Conduction Calculators
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Verified Boyle Temperature given Vander Waal Constants
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Verified Van der Waals Constant b given Boyle Temperature
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Verified Van der Waals Constant b given Inversion Temperature
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Verified Van der Waals Constant b given Inversion Temperature and Boltzmann Constant
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Verified Van der Waals Constant given Boyle Temperature
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Verified Van der Waals Constant given Inversion Temperature
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Verified Van der Waals Constant given Inversion Temperature and Boltzmann Constant
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11 More Van der Waals Constant Calculators
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Created Center-to-Center Distance
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Created Coefficient in Particle-Particle Pair Interaction
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Created Coefficient in Particle-Particle Pair Interaction given Van der Waals Pair Potential
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Created Concentration given Number Density
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Created Distance between Surfaces given Center-to-Center Distance
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Created Distance between Surfaces given Potential Energy in Limit of Close-Approach
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Created Distance between Surfaces given Van Der Waals Force between Two Spheres
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Created Distance between Surfaces given Van Der Waals Pair Potential
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Created Mass Density given Number density
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Created Mass of Single Atom
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Created Molar Mass given Number and Mass Density
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Created Potential Energy in Limit of Closest-Approach
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Created Radius of Spherical Body 1 given Center-to-Center Distance
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Created Radius of Spherical Body 1 given Potential Energy in Limit of Closest-Approach
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Created Radius of Spherical Body 1 given Van der Waals Force between Two Spheres
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Created Radius of Spherical Body 2 given Center-to-Center Distance
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Created Radius of Spherical Body 2 given Potential Energy in Limit of Closest-Approach
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Created Radius of Spherical Body 2 given Van Der Waals Force between Two Spheres
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Created Van der Waals Force between Two Spheres
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Created Van der Waals Interaction Energy between Two Spherical Bodies
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Created Van Der Waals Pair Potential
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Created Apparent Molar Mass given Van't Hoff factor
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Created Degree of Association given Van't Hoff Factor
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Created Degree of Dissociation given Van't Hoff Factor
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Created Experimental Osmotic Pressure given Van't Hoff Factor
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Created Formula Mass given Van't Hoff Factor
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Created Observed Molality given Van't Hoff Factor
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Created Observed Number of Particles given Van't Hoff Factor
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Created Observed or Experimental Value of Colligative Property given Van't Hoff Factor
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Created Theoretical Molality given Van't Hoff Factor
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Created Theoretical Number of Particles given Van't Hoff Factor
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Created Theoretical Osmotic Pressure given Van't Hoff Factor
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Created Theoretical Value of Colligative Property given Van't Hoff Factor
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Created Van't Hoff Factor given Colligative Property
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Created Van't Hoff Factor given Degree of Association
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Created Van't Hoff Factor given Degree of Dissociation
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Created Van't Hoff Factor given Experimental and Theoretical Osmotic Pressure
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Created Van't Hoff Factor given Molality
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Created Van't Hoff Factor given Molar Mass
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Created Van't Hoff Factor given Number of Particles
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Verified Vapour Density at Equilibrium given Molecular Weight Abnormal
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Verified Vapour Density at Equilibrium using Concentration of Reaction
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Verified Vapour Density at Equilibrium when Number of Moles of Products at Equilibrium is Half
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6 More Vapour Density at Equilibrium Calculators
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Verified Dimensionless Velocity for Fluidized Reactors at G/S Contacting Regime
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Verified Rate Constant of Phase between Bubble and Cloud
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Verified Terminal Velocity of Fluid for Spherical Particles
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Verified Velocity in Pneumatic Conveying
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6 More Various Fluidized Reactors Calculators
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Verified Volume of Mobile Phase given Capacity Factor and Partition Coefficient
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Verified Volume of Stationary Phase given Capacity Factor and Partition Coefficient
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4 More Volume and Concentration of Mobile and Stationary Phase Calculators
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Created Volume of cubic cell
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Created Volume of Hexagonal cell
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Created Volume of Monoclinic cell
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Created Volume of Orthorhombic cell
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Created Volume of Rhombohedral cell
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Created Volume of Tetragonal cell
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Created Volume of Triclinic cell
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4 More Volume of Different Cubic Cell Calculators
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Verified Volume of Distribution given Area under Curve
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Verified Volume of Distribution given Elimination Half Life
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Verified Volume of Distribution given Volume of Plasma Cleared
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Verified Volume of Distribution of Drug Displacing into Body Tissue Relative to Blood
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1 More Volume of Distribution Calculators
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Created Volume of Gas given Average Velocity and Pressure in 2D
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Created Volume of Gas given Most Probable Speed and Pressure in 2D
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Created Volume of Gas given Root Mean Square Speed and Pressure in 1D
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Created Volume of Gas given Root Mean Square Speed and Pressure in 2D
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5 More Volume of Gas Calculators
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Verified Fraction of Drug Unbound in Plasma given Plasma Volume
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Verified Volume of Plasma Cleared given Area under Curve
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Verified Volume of Plasma Cleared given Elimination Half Life
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Verified Volume of Plasma Cleared given Rate of Infusion
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Verified Volume of Plasma Cleared of Drug given Rate at which Drug is Removed
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Washing (21)
Verified Amount of Solvent Decanted
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Verified Amount of Solvent Remaining
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Verified Beta Value based on Number of Stages and Fraction of Solute
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Verified Beta Value based on Original Weight of Solute
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Verified Beta Value based on Ratio of Solvent
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Verified Fraction of Solute as Ratio of Solute
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Verified Fraction of Solute Remaining based on Beta Value
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Verified Fraction of Solute remaining based on Solvent Decanted
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Verified Number of Stages based on Original Weight of Solute
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Verified Number of Stages based on Solvent Decanted
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Verified Number of Stages for Leaching based on Fraction Solute Retained and Beta Value
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Verified Original Weight of Solute based on Number of Stages and Amount of Solvent Decanted
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Verified Original Weight of Solute based on Number of Stages and Beta Value
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Verified Original Weight of Solute in Solid before Washing
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Verified Solvent Decanted based on Fraction of Solute remaining and Number of Stages
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Verified Solvent Decanted based on Original Weight of Solute and Number of Stages
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Verified Solvent Remaining based on Fraction of Solute remaining and Number of Stages
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Verified Solvent Remaining based on Original Weight of Solute and Number of Stages
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Verified Weight of Solute remaining based on Number of Stages and Amount of Solvent Decanted
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Verified Weight of Solute remaining based on Number of Stages and Beta Value
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Verified Weight of Solute remaining in Solid
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Verified Bound Moisture Weight based on Free and Equilibrium Moisture Weight
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Verified Bound Moisture Weight based on Unbound Moisture Weight
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Verified Equilibrium Moisture Weight based on Bound and Unbound Moisture Weight
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Verified Equilibrium Moisture Weight based on Free Moisture Weight
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Verified Free Moisture Weight based on Bound and Unbound Moisture Weight
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Verified Free Moisture Weight based on Equilibrium Moisture Weight
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Verified Initial Moisture based on Free and Equlibrium Moisture Weight
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Verified Initial Moisture Weight based on Bound and Unbound Moisture Weight
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Verified Unbound Moisture Weight based on Bound Moisture Weight
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Verified Unbound Moisture Weight based on Free and Equilibrium Moisture Weight
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Verified Force for Rectangular Plate using Wilhelmy-Plate Method
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Verified Force given Surface Tension using Wilhelmy-Plate Method
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Verified Surface Pressure using Wilhelmy-Plate Method
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Verified Total Weight of Plate using Wilhelmy-Plate Method
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Verified Total Weight of Ring using Ring-Detachment Method
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Created Critical Pressure of Real Gas given Wohl Parameter a, and other Actual and Reduced Parameters
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Created Critical Pressure of Real Gas given Wohl Parameter b and other Actual and Reduced Parameters
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Created Critical Pressure of Real Gas given Wohl Parameter c and other Actual and Reduced Parameters
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Created Critical Pressure of Real Gas using Reduced Wohl Equation given Actual and Critical Parameters
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Created Critical Pressure of Real Gas using Reduced Wohl Equation given Actual and Reduced Parameters
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Created Critical Pressure of Real Gas using Wohl Equation given Reduced and Actual Parameters
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Created Critical Pressure of Real Gas using Wohl Equation given Reduced and Critical Parameters
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Created Critical Pressure of Real Gas using Wohl Equation given Wohl Parameter a
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Created Critical Pressure of Real Gas using Wohl Equation given Wohl Parameter b
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Created Critical Pressure of Real Gas using Wohl Equation given Wohl Parameter c
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Created Critical Pressure of Wohl's Real Gas using other Actual and Reduced Parameters
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Created Critical Pressure of Wohl's Real Gas using other Critical Parameters
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Created Reduced Pressure of Real Gas given Wohl Parameter a, and Actual and Critical Parameters
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Created Reduced Pressure of Real Gas given Wohl Parameter b and Actual and Critical Parameters
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Created Reduced Pressure of Real Gas given Wohl Parameter b and Actual and Reduced Parameters
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Created Reduced Pressure of Real Gas given Wohl Parameter c and Actual and Critical Parameters
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Created Reduced Pressure of Real Gas given Wohl Parameter c and Actual and Reduced Parameters
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Created Reduced Pressure of Real Gas using Reduced Wohl Equation given Actual and Critical Parameters
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Created Reduced Pressure of Real Gas using Reduced Wohl Equation given Reduced Parameters
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Created Reduced Pressure of Real Gas using Wohl Equation given Critical and Actual Parameters
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Created Reduced Pressure of Real Gas using Wohl Equation given Reduced and Critical Parameters
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Created Reduced Pressure of Real Gas using Wohl parameter a, and Actual and Reduced Parameters
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Created Reduced Pressure of Wohl's Real Gas using other Actual and Critical Parameters
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Created Reduced Pressure of Wohl's Real Gas using other Actual and Reduced Parameters
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Created Wohl Parameter (a) of Real Gas using Actual and Reduced Parameters
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Created Wohl Parameter (a) of Real Gas using Wohl Equation
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Created Wohl Parameter (a) of Real Gas using Wohl Equation given Actual and Critical Parameters
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Created Wohl Parameter (a) of Real Gas using Wohl Equation given Actual and Reduced Parameters
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Created Wohl Parameter (a) of Real Gas using Wohl Equation given Critical Parameters
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Created Wohl Parameter (a) of Real Gas using Wohl Equation given Reduced and Critical Parameters
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Created Wohl Parameter (b) of Real Gas given Actual and Reduced Molar Volume
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Created Wohl Parameter (b) of Real Gas given Actual and Reduced Temperature and Pressure
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Created Wohl Parameter (b) of Real Gas using Wohl Equation
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Created Wohl Parameter (b) of Real Gas using Wohl Equation given Actual and Critical Parameters
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Created Wohl Parameter (b) of Real Gas using Wohl Equation given Actual and Reduced Parameters
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Created Wohl Parameter (b) of Real Gas using Wohl Equation given Critical Molar Volume
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Created Wohl Parameter (b) of Real Gas using Wohl Equation given Critical Temperature and Pressure
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Created Wohl Parameter (b) of Real Gas using Wohl Equation given Reduced and Critical Parameters
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Created Wohl Parameter (c) of Real Gas given Actual and Reduced Parameters
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Created Wohl Parameter (c) of Real Gas using Wohl Equation
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Created Wohl Parameter (c) of Real Gas using Wohl Equation given Actual and Critical Parameters
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Created Wohl Parameter (c) of Real Gas using Wohl Equation given Actual and Reduced Parameters
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Created Wohl Parameter (c) of Real Gas using Wohl Equation given Critical Parameters
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Created Wohl Parameter (c) of Real Gas using Wohl Equation given Reduced and Critical Parameters
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Verified Nominal HP of Driving Motor
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2 More Work Required Calculators
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Verified Initial Concentration of Reactant in Zero Order Reaction followed by First Order Reaction
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Verified Initial Reactant Concentration by Intermediate Conc. for Zero Order followed by First Order Rxn
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Verified Initial Reactant Concentration using Intermediate Conc. for Zero Order followed by First Order Rxn
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Verified Intermediate Concentration for Zero Order followed by First Order with Greater Rxn Time
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Verified Intermediate Concentration for Zero Order followed by First Order with Less Rxn Time
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Verified Maximum Intermediate Concentration in Zero Order followed by First Order
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Verified Rate Constant of Zero Order Reaction in Zero Order Reaction followed by First Order Reaction
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Verified Reactant Concentration of Zero Order Reaction followed by First Order Reaction
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Verified Time at Max Intermediate in Zero Order followed by First Order Reaction
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