Calculators Created by Prerana Bakli

Verified Activities of electrolyte given concentration and fugacity

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Verified Activity coefficient given the ionic activity

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Verified Activity coefficient of anodic electrolyte of concentration cell with transference

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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 with 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 in terms of 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 in terms of valencies

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Verified Activity of cathodic electrolyte of concentration cell without transference

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Created Allred Rochow's Electronegativity given IE and EA

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Created Allred Rochow's Electronegativity in terms of bond energies

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Created Allred Rochow's Electronegativity of an element

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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 an element using Allred Rochow's Electronegativity

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Created Ionization Energy of an element using Allred Rochow's Electronegativity

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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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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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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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Verified Beer-Lambert law in terms of 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 a of Real Gas

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Created Berthelot parameter a of Real Gas in terms of critical and reduced parameters

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Created Berthelot parameter b of Real Gas

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Created Berthelot parameter b of Real Gas in terms of critical and reduced parameters

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Created Critical Molar Volume using Modified Berthelot equation in terms of reduced and actual parameters

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Created Critical Pressure using Modified Berthelot equation in terms of reduced and actual parameters

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Created Critical Temperature using Modified Berthelot equation in terms of 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 in terms of critical and reduced parameters

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Created Molar Volume using Modified Berthelot equation in terms of critical and actual parameters

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Created Molar Volume using Modified Berthelot equation in terms of critical and reduced parameters

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Created Molar Volume using Modified Berthelot equation in terms of 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 in terms of critical and reduced parameters

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Created Pressure using Modified Berthelot equation in terms of reduced and actual parameters

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Created Reduced Molar Volume using Modified Berthelot equation in terms of critical and actual parameters

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Created Reduced Pressure using Modified Berthelot equation in terms of actual parameters

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Created Reduced Temperature using Modified Berthelot equation in terms of 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 in terms of critical and reduced parameters

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Created Temperature using Modified Berthelot equation in terms of reduced and actual parameters

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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 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 Retention volume given capacity factor

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Verified Unretained volume given capacity factor

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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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5 More Cationic Salt Hydrolysis Calculators

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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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Created Actual Pressure of real gas using Clausius parameter a, actual and critical parameters

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Created Actual Pressure of real gas using Clausius parameter a, reduced and actual parameters

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Created Actual Pressure of real gas using Clausius parameter a, reduced and critical parameters

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Created Actual Pressure of real gas using Clausius parameter b, actual and critical parameters

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Created Actual Pressure of real gas using Clausius parameter b, reduced and actual parameters

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Created Actual Pressure of real gas using Clausius parameter b, reduced and critical parameters

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Created Actual Pressure of real gas using Clausius parameter c, actual and critical parameters

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Created Actual Pressure of real gas using Clausius parameter c, reduced and actual parameters

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Created Actual Pressure of real gas using Clausius parameter c, reduced and critical parameters

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Created Actual Temperature of real gas using Clausius parameter a, actual and critical parameters

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Created Actual Temperature of real gas using Clausius parameter a, reduced and actual parameters

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Created Actual Temperature of real gas using Clausius parameter a, reduced and critical parameters

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Created Actual Temperature of real gas using Clausius parameter b, actual and critical parameters

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Created Actual Temperature of real gas using Clausius parameter b, reduced and actual parameters

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Created Actual Temperature of real gas using Clausius parameter b, reduced and critical parameters

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Created Actual Temperature of real gas using Clausius parameter c, actual and critical parameters

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Created Actual Temperature of real gas using Clausius parameter c, reduced and actual parameters

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Created Actual Temperature of real gas using Clausius parameter c, reduced and critical 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 Clausius parameter a in terms of critical parameters

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Created Clausius parameter a in terms of Pressure, Temperature and Molar Volume of real gas

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Created Clausius parameter a in terms of reduced and actual parameters

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Created Clausius parameter a in terms of reduced and critical parameters using Clausius equation

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Created Clausius parameter b in terms of critical parameters

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Created Clausius parameter b in terms of Pressure, Temperature and Molar Volume of real gas

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Created Clausius parameter b in terms of reduced and actual parameters

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Created Clausius parameter b in terms of reduced and critical parameters using Clausius equation

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Created Clausius parameter c in terms of critical parameters

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Created Clausius parameter c in terms of Pressure, Temperature and Molar Volume of real gas

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Created Clausius parameter c in terms of reduced and actual parameters

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Created Clausius parameter c in terms of reduced and critical parameters using Clausius equation

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Created Critical Molar Volume of real gas using Clausius equation in terms of reduced and actual parameters

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Created Critical Molar Volume using Clausius equation in terms of actual and critical parameters

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Created Critical Molar Volume using Clausius equation in terms of reduced and critical parameters

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Created Critical Pressure of real gas using Clausius equation in terms of actual and critical parameters

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Created Critical Pressure of real gas using Clausius equation in terms of reduced and actual parameters

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Created Critical Pressure of real gas using Clausius equation in terms of reduced and critical parameters

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Created Critical Pressure of real gas using Clausius parameter a

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Created Critical Pressure of real gas using Clausius parameter b

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Created Critical Pressure of real gas using Clausius parameter c

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Created Critical Pressure using Clausius parameter a in terms of reduced and actual parameters

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Created Critical Pressure using Clausius parameter b in terms of reduced and actual parameters

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Created Critical Pressure using Clausius parameter c in terms of reduced and actual parameters

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Created Critical Temperature of real gas using Clausius equation in terms of actual and critical parameters

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Created Critical Temperature of real gas using Clausius equation in terms of reduced and actual parameters

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Created Critical Temperature of real gas using Clausius equation in terms of reduced and critical parameters

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Created Critical Temperature of real gas using Clausius parameter a

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Created Critical Temperature of real gas using Clausius parameter b

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Created Critical Temperature of real gas using Clausius parameter c

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Created Critical Temperature using Clausius parameter a in terms of reduced and actual parameters

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Created Critical Temperature using Clausius parameter b in terms of reduced and actual parameters

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Created Critical Temperature using Clausius parameter c in terms of reduced and actual parameters

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Created Critical Volume of real gas using Clausius parameter b

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Created Critical Volume of real gas using Clausius parameter c

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Created Critical Volume using Clausius parameter b in terms of reduced and actual parameters

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Created Critical Volume using Clausius parameter c in terms of reduced and actual parameters

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Created Molar Volume of real gas using Clausius equation

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Created Molar Volume of real gas using Clausius equation in terms of reduced and critical parameters

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Created Pressure of real gas using Clausius equation

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Created Pressure of real gas using Clausius equation in terms of reduced and critical parameters

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Created Reduced Molar Volume of real gas using Clausius equation in terms of critical and actual parameters

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Created Reduced Molar Volume of real gas using Clausius equation in terms of reduced and actual parameters

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Created Reduced Molar Volume of real gas using Clausius equation in terms of reduced and critical parameters

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Created Reduced Pressure of real gas using Clausius equation in terms of critical and actual parameters

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Created Reduced Pressure of real gas using Clausius equation in terms of reduced and actual parameters

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Created Reduced Pressure of real gas using Clausius equation in terms of reduced and critical parameters

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Created Reduced Pressure of real gas using Clausius parameter a and actual parameters

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Created Reduced Pressure of real gas using Clausius parameter a, reduced and actual parameters

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Created Reduced Pressure of real gas using Clausius parameter b and actual parameters

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Created Reduced Pressure of real gas using Clausius parameter b, reduced and actual parameters

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Created Reduced Pressure of real gas using Clausius parameter c and actual parameters

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Created Reduced Pressure of real gas using Clausius parameter c, reduced and actual parameters

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Created Reduced Temperature of real gas using Clausius equation in terms of critical and actual parameters

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Created Reduced Temperature of real gas using Clausius equation in terms of reduced and actual parameters

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Created Reduced Temperature of real gas using Clausius equation in terms of reduced and critical parameters

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Created Reduced Temperature of real gas using Clausius parameter a and actual parameters

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Created Reduced Temperature of real gas using Clausius parameter a, reduced and actual parameters

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Created Reduced Temperature of real gas using Clausius parameter b and actual parameters

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Created Reduced Temperature of real gas using Clausius parameter b, reduced and actual parameters

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Created Reduced Temperature of real gas using Clausius parameter c and actual parameters

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Created Reduced Temperature of real gas using Clausius parameter c, reduced and actual parameters

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Created Reduced Volume of real gas using Clausius parameter b and actual parameters

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Created Reduced Volume of real gas using Clausius parameter b, reduced and actual parameters

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Created Reduced Volume of real gas using Clausius parameter c and actual parameters

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Created Reduced Volume of real gas using Clausius parameter c, reduced and actual 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 in terms of reduced and critical parameters

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Created August Roche Magnus formula

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Created Boiling Point using Trouton's Rule in terms of enthalpy

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Created Boiling Point using Trouton's Rule in terms of Latent Heat

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Created Boiling Point using Trouton's Rule in terms of 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 Latent heat of evaporation of water near standard temperature and pressure

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Created Latent Heat of vaporization for transitions

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Created Latent Heat using integrated form of Clausius-Clapeyron Equation

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Created Latent Heat using Trouton's Rule

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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 Slope of coexistence curve in terms of enthalpy

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Created Slope of coexistence curve in terms of entropy

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Created Slope of coexistence curve in terms of Latent Heat

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Created Slope of coexistence curve in terms of pressure and latent heat

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Created Slope of coexistence curve in terms of 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 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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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 the system

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Verified Initial rate of the 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 Modifing 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 an enzymatic reaction mechanism

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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 material using Isentropic compressibility

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Created Density using relative size of fluctuations in particle density

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Created Isentropic compressibility

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Created Isentropic compressibility given Molar Heat Capacity at constant Pressure and Volume

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Created Isentropic compressibility given Molar Heat Capacity Ratio

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Created Isentropic compressibility given thermal pressure coefficient and Cp

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Created Isentropic compressibility given thermal pressure coefficient and Cv

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Created Isentropic compressibility given volumetric coefficient of thermal expansion and Cp

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Created Isentropic compressibility given volumetric coefficient of thermal expansion and Cv

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Created Isothermal compressibility given Molar Heat Capacity at constant Pressure and Volume

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Created Isothermal compressibility given Molar Heat Capacity Ratio

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Created Isothermal compressibility given thermal pressure coefficient and Cp

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Created Isothermal compressibility given thermal pressure coefficient and Cv

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Created Isothermal compressibility given volumetric coefficient of thermal expansion and Cp

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Created Isothermal compressibility given volumetric coefficient of thermal expansion and Cv

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Created Isothermal compressibility using relative size of fluctuations in particle density

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Created Molar Heat Capacity at constant Pressure given thermal pressure coefficient

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Created Molar Heat Capacity at constant Pressure given volumetric coefficient of thermal expansion

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Created Molar Heat Capacity at constant Pressure in terms of Compressibility

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Created Molar Heat Capacity at constant Volume given thermal pressure coefficient

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Created Molar Heat Capacity at constant Volume given volumetric coefficient of thermal expansion

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Created Molar Heat Capacity at constant Volume in terms of Compressibility

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Created Ratio Molar Heat Capacity in terms of Compressibility

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Created Relative size of fluctuations in particle density

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Created Speed of sound using Isentropic compressibility

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Created Temperature given coefficient of thermal expansion, compressibility factors and Cp

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Created Temperature given coefficient of thermal expansion, compressibility factors and Cv

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Created Temperature given thermal pressure coefficient, compressibility factors and Cp

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Created Temperature given thermal pressure coefficient, compressibility factors and Cv

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Created Temperature using relative size of fluctuations in particle density

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Created Thermal pressure coefficient using compressibility factors and Cp

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Created Thermal pressure coefficient using compressibility factors and Cv

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Created Volume using relative size of fluctuations in particle density

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Created Volumetric coefficient of thermal expansion using compressibility factors and Cp

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Created Volumetric coefficient of thermal expansion using compressibility factors and Cv

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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 with transference

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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 with transference

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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 Molality using number of moles and mass of solvent

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Created Molarity of substance

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Created Number of moles of solute using molality

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21 More Concentration terms 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 Equivalent conductance given normality

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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 Normality given equivalent conductance

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Verified Specific conductance given molarity

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Verified Specific conductivity given equivalent conductivity and normality of solution

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10 More Conductance and Conductivity Calculators

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Created Bond Angle between Bond pair and Lone pair of electrons in terms of p character

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Created Bond Angle between Bond pair and Lone pair of electrons in terms of s character

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Created Bond Order for Molecules Showing Resonance

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Created Formal Charge on an 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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Verified Concentration of gas to determine volume-based concentration by Dalton's law

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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 Charge number of ion species using Debey-Huckel limiting law

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Verified Debey-Huckel limiting law constant

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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 Cryoscopic Constant given Depression in Freezing Point

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Created Cryoscopic Constant in terms of Latent Heat of Fusion

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Created Cryoscopic Constant in terms of Molar Enthalpy of Fusion

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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 Van't Hoff equation for Depression in Freezing Point of electrolyte

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Created Van't Hoff Factor of an Electrolyte in terms of Depression in Freezing Point

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5 More Depression in Freezing Point Calculators

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Verified Bending Stress given Normal Stress

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Verified Normal Stress given Principal Shear Stress in Shaft - Bending & Torsion

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13 More Desgin of Shafts Calculators

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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 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 a given volume of plasma

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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 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 Actual mass given current efficiency

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Verified Cell potential given electrochemical work

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Verified Excess pressure given the osmotic coefficient

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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 Ideal pressure given osmotic coefficient

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Verified Ionic activity given molality of a solution

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Verified Number of positive and negative ions of concentration cell with transference

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Verified Osmotic coefficient given ideal and excess pressure

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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 in terms of valencies

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Verified Valencies of positive and negative ions of concentration cell with transference

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9 More Electrochemistry 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 in terms of Latent Heat of Vaporization

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Created Ebullioscopic Constant in terms of Molar Enthalpy of Vaporization

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Created Elevation in Boiling Point of the 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 Van't Hoff equation for Elevation in Boiling Point of electrolyte

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Created Van't Hoff Factor of an Electrolyte in terms of Elevation in Boiling Point

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5 More Elevation in Boiling Point Calculators

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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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1 More EMF of concentration cell 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 in 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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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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12 More Equilibrium 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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6 More Equilibrium constant Calculators

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Verified Equilibrium constant with respect to mole fraction

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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 constant with respect to partial pressure

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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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Created Atomicity given Molar Heat Capacity at constant pressure of Linear Molecule

Go

Created Atomicity given Molar Heat Capacity at constant pressure of Non-Linear Molecule

Go

Created Atomicity given Molar Heat Capacity at constant volume of Linear Molecule

Go

Created Atomicity given Molar Heat Capacity at constant volume of Non-Linear Molecule

Go

Created Atomicity using Average thermal energy of linear polyatomic gas molecule

Go

Created Atomicity using Average thermal energy of non-linear polyatomic gas molecule

Go

Created Atomicity using Internal Molar Energy of Linear Molecule

Go

Created Atomicity using Internal Molar Energy of Non-Linear Molecule

Go

Created Atomicity using Molar Heat Capacity at constant Pressure and Volume of Linear Molecule

Go

Created Atomicity using Molar Heat Capacity at constant Pressure and Volume of Non-Linear Molecule

Go

Created Atomicity using Molar Vibrational Energy of Linear Molecule

Go

Created Atomicity using Molar Vibrational Energy of Non-Linear Molecule

Go

Created Atomicity using Number of modes in Linear Molecule

Go

Created Atomicity using Number of modes in Non-Linear Molecule

Go

Created Atomicity using Ratio of Molar Heat Capacity of Linear Molecule

Go

Created Atomicity using Ratio of Molar Heat Capacity of Non-Linear Molecule

Go

Created Atomicity using Vibrational Degree of Freedom in Linear Molecule

Go

Created Atomicity using Vibrational Degree of Freedom in Non-Linear Molecule

Go

Created Atomicity using Vibrational Energy of Linear Molecule

Go

Created Atomicity using Vibrational Energy of Non-Linear Molecule

Go

Created Atomicity using Vibrational Mode of Linear Molecule

Go

Created Atomicity using Vibrational Mode of Non-Linear Molecule

Go

Created Average thermal energy of linear polyatomic gas molecule

Go

Created Average thermal energy of linear polyatomic gas molecule in terms of atomicity only

Go

Created Average thermal energy of non-linear polyatomic gas molecule

Go

Created Average thermal energy of non-linear polyatomic gas molecule in terms of atomicity only

Go

Created Degree of Freedom given Ratio of Molar Heat Capacity

Go

Created Degree of Freedom in Linear Molecule

Go

Created Degree of Freedom in Non-Linear Molecule

Go

Created Degree of Freedom in terms of Molar Heat Capacity at constant pressure only

Go

Created Degree of Freedom in terms of Molar Heat Capacity at constant volume and pressure

Go

Created Degree of Freedom in terms of Molar Heat Capacity at constant volume only

Go

Created Heat Capacity

Go

Created Heat Capacity given Specific Heat Capacity

Go

Created Internal Molar Energy of Linear Molecule

Go

Created Internal Molar Energy of Linear Molecule in terms of atomicity only

Go

Created Internal Molar Energy of Non-Linear Molecule

Go

Created Internal Molar Energy of Non-Linear Molecule in terms of atomicity only

Go

Created Molar Heat Capacity at constant pressure given only Degree of Freedom

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 only Degree of Freedom

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 Vibrational Energy of Linear Molecule

Go

Created Molar Vibrational Energy of Non-Linear Molecule

Go

Created Number of modes in Linear Molecule

Go

Created Number of modes in Non-Linear Molecule

Go

Created Ratio of Molar Heat Capacity

Go

Created Ratio of Molar Heat Capacity given Degree of Freedom

Go

Created Ratio of Molar Heat Capacity in terms of Molar Heat Capacity at constant pressure only

Go

Created Ratio of Molar Heat Capacity in terms of Molar Heat Capacity at constant volume only

Go

Created Ratio of Molar Heat Capacity of Linear Molecule

Go

Created Ratio of Molar Heat Capacity of Non-Linear Molecule

Go

Created Rotational Energy of Linear Molecule

Go

Created Rotational Energy of Non-Linear Molecule

Go

Created Specific Heat Capacity given Heat Capacity

Go

Created Specific Heat Capacity in terms of heat capacity

Go

Created Temperature using Average thermal energy of linear polyatomic gas molecule

Go

Created Temperature using Average thermal energy of non-linear polyatomic gas molecule

Go

Created Temperature using Internal Molar Energy of Linear Molecule

Go

Created Temperature using Internal Molar Energy of Non-Linear Molecule

Go

Created Temperature using Molar Vibrational Energy of Linear Molecule

Go

Created Temperature using Molar Vibrational Energy of Non-Linear Molecule

Go

Created Temperature using Vibrational Energy of Linear Molecule

Go

Created Temperature using Vibrational Energy of Non-Linear Molecule

Go

Created Total Kinetic Energy

Go

Created Translational Energy

Go

Created Vibrational energy modeled as harmonic oscillator

Go

Created Vibrational Energy of Linear Molecule

Go

Created Vibrational Energy of Non-Linear Molecule

Go

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

Go

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

Go

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 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 Cell potential given change in Gibbs free energy

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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 Gibbs free energy 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 Standard Cell potential given change in Standard change in Gibbs free energy

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Verified Standard change in Gibbs free energy given standard cell potential

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1 More Gibbs free energy Calculators

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Verified Classical part of Gibbs free entropy given electric part

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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

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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 Gibbs free entropy given Helmholtz free entropy

Go

Verified Helmholtz free entropy given Gibbs free entropy

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Verified Internal energy given Gibbs free entropy

Go

Verified Pressure given Gibbs free entropy

Go

Verified Volume given Gibbs free entropy

Go

Created Number of Components considering reactions and constraints

Go

Verified Density of first gas by Graham's law

Go

Verified Density of second gas by Graham's law

Go

Verified Molar mass of first gas by Graham's law

Go

Verified Molar mass of second gas by Graham's law

Go

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

Go

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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Verified Helmholtz free energy given Helmholtz free entropy and temperature

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Verified Volume given Gibbs and Helmholtz free entropy

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Verified Classical part of Helmholtz free entropy given electric part

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Verified Electric part of Helmholtz free entropy given classical part

Go

Verified Entropy given internal energy and Helmholtz free entropy

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Verified Helmholtz free entropy

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Verified Helmholtz free entropy given classical and electric part

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Verified Helmholtz free entropy given Helmholtz free energy

Go

Verified Internal energy given Helmholtz free entropy and entropy

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Verified Pressure given Gibbs and Helmholtz free entropy

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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

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Verified Final pressure of gas given density

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Verified Final temperature of gas by ideal gas law

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Verified Final temperature of gas given density

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Verified Final volume of gas by ideal gas law

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Verified Initial density of gas by ideal gas law

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Verified Initial pressure of gas by ideal gas law

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Verified Initial pressure of gas given density

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Verified Initial temperature of gas by ideal gas law

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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

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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

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Verified Pressure by ideal gas law

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Verified Pressure of gas given density by ideal gas law

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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

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Verified Temperature of gas given density by ideal gas law

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Verified Temperature of gas given molecular weight of gas by ideal gas law

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Verified Volume of gas from ideal gas law

Go

Verified Volume of gas given molecular weight of gas by ideal gas law

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Created Molecular Mass of a liquid forming an immiscible mixture with Water

Go

Created Molecular Mass of liquid in mixture of 2 immiscible liquids given weights of liquids

Go

Created Partial Vapour Pressure of immiscible liquid given partial pressure of other

Go

Created Ratio of Molecular Mass of 2 immiscible liquids

Go

Created Ratio of molecular masses of water to a liquid forming a immiscible mixture

Go

Created Ratio of partial pressure of 2 immiscible liquids in terms their number of moles

Go

Created Ratio of partial vapour pressures of 2 Immiscible Liquids in terms of weight and molecular mass

Go

Created Ratio of partial vapour pressures of water with a liquid forming a immiscible mixture

Go

Created Ratio of weights of 2 immiscible liquids forming a mixture

Go

Created Ratio of weights of water to a liquid forming a 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 a liquid forming an immiscible mixture with Water

Go

Created Vapour Pressure of water forming an immiscible mixture with a liquid

Go

Created Weight of a liquid required to form a immiscible mixture with water

Go

Created Weight of liquid in mixture of 2 immiscible liquids given weight of other liquid

Go

Created Weight of water required to form immiscible mixture with liquid given weight

Go

Created Interplanar angle for Hexagonal system

Go

Created Interplanar angle for Orthorhombic system

Go

Created Interplanar angle for Rhombohedral system

Go

Created Interplanar angle for Simple Cubic system

Go

Created Interplanar angle for Triclinic 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

Created Charge of ion using Ionic Potential

Go

Created Ionic Potential

Go

Created Radius of ion using 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 for uni-univalent electrolyte if molality of cation and anion is same

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 Acentric factor

Go

Created Acentric factor using actual and critical saturation vapor pressure

Go

Created Average velocity of gas given pressure and density in 2D

Go

Created Average velocity of gas given pressure and volume in 2D

Go

Created Average velocity of gas given root mean square speed in 2D

Go

Created Average velocity of gas given temperature in 2D

Go

Verified Boyle temperature given Inversion temperature

Go

Verified Boyle temperature given Vander Waal constants

Go

Verified Critical temperature given inversion temperature

Go

Created Density of gas given average velocity and pressure in 2D

Go

Created Density of gas given most probable speed pressure in 2D

Go

Created Density of gas given root mean square speed and pressure in 1D

Go

Created Density of gas given root mean square speed and pressure in 2D

Go

Verified Inversion temperature given Boyle temperature

Go

Verified Inversion temperature given critical temperature

Go

Verified Inversion temperature given Vander Waal constants

Go

Verified Inversion temperature given Vander Waals constants and Boltzmann constant

Go

Verified Kinetic energy of one gas molecule in the term of Boltzmann constant

Go

Created Mass of each gas molecule in 2D box if pressure is given

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

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 pressure in 2D

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 2D

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

Created Number of gas molecules in 2D box given pressure

Go

Created Pressure of gas given average velocity and density in 2D

Go

Created Pressure of gas given average velocity and volume in 2D

Go

Created Pressure of gas given most probable speed and density in 2D

Go

Created Pressure of gas given most probable speed and volume in 2D

Go

Created Pressure of gas given root mean square speed and density in 1D

Go

Created Pressure of gas given root mean square speed and density in 2D

Go

Created Pressure of gas given root mean square speed and Volume in 1D

Go

Created Pressure of gas given root mean square speed and Volume in 2D

Go

Created Pressure of gas molecules in 1D box

Go

Created Pressure of gas molecules in 2D box

Go

Created RMS velocity given most probable velocity in 2D

Go

Created RMS velocity in terms of pressure and density in 1D

Go

Created RMS velocity in terms of pressure and density in 2D

Go

Created RMS velocity in terms of pressure and volume of gas in 1D

Go

Created RMS velocity in terms of pressure and volume of gas in 2D

Go

Created RMS velocity in terms of temperature and molar mass in 1D

Go

Created RMS velocity in terms of temperature and molar mass in 2D

Go

Created Root mean square speed given average velocity in 2D

Go

Created Temperature given most probable speed and molar mass in 2D

Go

Created Temperature of gas given average velocity in 2D

Go

Created Temperature of gas given root mean square speed and molar mass in 1D

Go

Created Temperature of gas given root mean square speed and molar mass in 2D

Go

Verified Temperature of one gas molecule in terms of Boltzmann constant

Go

Verified Vander Waal constant b given Boyle temperature

Go

Verified Vander Waal constant b given inversion temperature

Go

Verified Vander Waal constant b given Inversion temperature and Boltzmann constant

Go

Verified Vander Waal constant given Boyle temperature

Go

Verified Vander Waal constant given inversion temperature

Go

Verified Vander Waals constant given Inversion temperature and Boltzmann constant

Go

Created Volume of gas given average velocity and pressure in 2D

Go

Created Volume of gas given most probable speed and pressure in 2D

Go

Created Volume of gas given root mean square speed and Pressure in 1D

Go

Created Volume of gas given root mean square speed and Pressure in 2D

Go

78 More Kinetic Theory of Gases Calculators

Go

Created Born exponent using Born Landé equation

Go

Created Born exponent using Born Landé equation when Madelung constant is not given

Go

Created Born exponent using Repulsive Interaction

Go

Created Constant depending on compressibility using Born–Mayer equation

Go

Created Distance of closest approach using Born Landé equation

Go

Created Distance of closest approach using Born Landé equation when Madelung constant is not given

Go

Created Distance of closest approach using Electrostatic potential

Go

Created Distance of closest approach using Madelung Energy

Go

Created Electrostatic potential energy between a pair of ions

Go

Created Lattice Energy using Born–Landé equation

Go

Created Lattice Energy using Born–Landé 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 Madelung constant given Repulsive Interaction Constant

Go

Created Madelung constant using Born Landé 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 an ion

Go

Created Madelung constant using Total Energy of an ion given Repulsive Interaction

Go

Created Madelung Energy

Go

Created Madelung Energy using Total Energy of an ion

Go

Created Madelung Energy using Total Energy of an ion in terms of distance

Go

Created Minimum Potential Energy of an 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 using Total Energy of an ion

Go

Created Repulsive Interaction Constant using Total Energy of ion given Madelung Energy

Go

Created Repulsive Interaction using Total Energy of an ion

Go

Created Repulsive Interaction using Total Energy of an ion in terms of charges and distances

Go

Created Total Energy of an ion in terms of charges and distances

Go

Created Total Energy of an ion in the 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

8 More Length of column Calculators

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

Verified Mobile phase travel time through column

Go

Verified Number of theoretical plates given resolution and separation factor

Go

Verified Resolution given number of theoretical plates and separation factor

Go

Verified Resolution of two peaks given half of average width of peaks

Go

Verified Retention volume given flow rate

Go

Verified Separation factor given resolution and number of theoretical plates

Go

Verified Standard deviation given retention time and number of theoretical plates

Go

18 More Method of separation technique Calculators

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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

Created Covalent radius given Mulliken's Electronegativity

Go

Created Effective Nuclear Charge given Mulliken's Electronegativity

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

Created Degrees of Freedom of One Component System

Go

Created Number of Phases of One Component System

Go

Verified Absorption half life of drug

Go

Verified Apparent tissue volume given plasma volume and apparent volume

Go

Verified Apparent volume of drug distribution

Go

Verified Average plasma concentration given area under curve

Go

Verified Average plasma concentration given peak through fluctuation

Go

Verified Concentration of drug given rate of infusion of drug

Go

Verified Drug purity given Administrative dose and Effective dose

Go

Verified Drug purity given rate of administration and dosing interval

Go

Verified Elimination half life given volume of plasma cleared

Go

Verified Elimination half life of drug

Go

Verified Elimination rate constant given area under curve

Go

Verified Elimination rate constant given volume of plasma cleared

Go

Verified Elimination rate constant of drug

Go

Verified Fraction of drug unbound in plasma given plasma volume

Go

Verified Fraction of drug unbound in tissue given apparent tissue volume

Go

Verified Lowest plasma concentration given peak through fluctuation

Go

Verified Peak plasma concentration given peak through fluctuation

Go

Verified Peak through fluctuation

Go

Verified Plasma volume of drug given apparent volume

Go

Verified Rate at which drug enters into body

Go

Verified Rate of administration of drug given dosing interval

Go

Verified Rate of infusion of drug

Go

Verified Relative bioavailability of drug

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 volume and concentration of two substances

Go

Created Osmotic pressure given volume and osmotic pressure of two substances

Go

Created Osmotic pressure in terms of number of moles and volume of solution

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 an Electrolyte

Go

Created Van't Hoff Osmotic Pressure for mixture of 2 solutions

Go

Created Volume of solution given osmotic pressure

Go

Created Actual Pressure in terms of Peng Robinson parameter a and other actual and reduced parameters

Go

Created Actual Pressure in terms of Peng Robinson parameter a and other reduced and critical parameters

Go

Created Actual Pressure in terms of Peng Robinson parameter b and other actual and reduced parameters

Go

Created Actual Pressure in terms of Peng Robinson parameter b and other reduced and critical parameters

Go

Created Actual Temperature for Peng Robinson equation using alpha-function and pure component parameter

Go

Created Actual Temperature in terms of Peng Robinson parameter a and other actual and reduced parameters

Go

Created Actual Temperature in terms of Peng Robinson parameter a and other reduced and critical parameters

Go

Created Actual Temperature in terms of Peng Robinson parameter b and other actual and reduced parameters

Go

Created Actual Temperature in terms of Peng Robinson parameter b and other reduced and critical parameters

Go

Created Alpha-function for Peng Robinson equation of state using critical and actual temperature

Go

Created Alpha-function for Peng Robinson equation of state using reduced temperature

Go

Created Critical Pressure in terms of Peng Robinson parameter a and other actual and reduced parameters

Go

Created Critical Pressure in terms of Peng Robinson parameter b and other actual and reduced parameters

Go

Created Critical Pressure of real gas using Peng Robinson equation in terms of Peng Robinson parameter a

Go

Created Critical Pressure of real gas using Peng Robinson equation in terms of Peng Robinson parameter b

Go

Created Critical Pressure of real gas using Peng Robinson equation in terms of reduced and actual parameters

Go

Created Critical Pressure using Peng Robinson equation in terms of reduced and critical parameters

Go

Created Critical Temperature for Peng Robinson equation using alpha-function and pure component parameter

Go

Created Critical Temperature in terms of Peng Robinson parameter a and other actual and reduced parameters

Go

Created Critical Temperature in terms of Peng Robinson parameter b and other actual and reduced parameters

Go

Created Critical Temperature of real gas using Peng Robinson equation in terms of Peng Robinson parameter a

Go

Created Critical Temperature of real gas using Peng Robinson equation in terms of Peng Robinson parameter b

Go

Created Critical Temperature using Peng Robinson equation in terms of reduced and actual parameters

Go

Created Critical Temperature using Peng Robinson equation in terms of reduced and critical parameters

Go

Created Peng Robinson alpha-function using Peng Robinson equation

Go

Created Peng Robinson alpha-function using Peng Robinson equation for reduced and critical parameters

Go

Created Peng Robinson parameter a of real gas in terms of critical parameters

Go

Created Peng Robinson parameter a of real gas in terms of reduced and actual parameters

Go

Created Peng Robinson parameter a using Peng Robinson equation

Go

Created Peng Robinson parameter a using Peng Robinson equation in terms of reduced and critical parameters

Go

Created Peng Robinson parameter b of real gas in terms of critical parameters

Go

Created Peng Robinson parameter b of real gas in terms of reduced and actual parameters

Go

Created Pressure of real gas using Peng Robinson equation

Go

Created Pressure of real gas using Peng Robinson equation in terms of 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 Reduced Pressure in terms of Peng Robinson parameter a and other actual and critical parameters

Go

Created Reduced Pressure in terms of Peng Robinson parameter a and other actual and reduced parameters

Go

Created Reduced Pressure in terms of Peng Robinson parameter b and other actual and critical parameters

Go

Created Reduced Pressure in terms of Peng Robinson parameter b and other actual and reduced parameters

Go

Created Reduced Pressure using Peng Robinson equation in terms of critical and actual parameters

Go

Created Reduced Pressure using Peng Robinson equation in terms of reduced and critical parameters

Go

Created Reduced Temperature for Peng Robinson equation using alpha-function and pure component parameter

Go

Created Reduced Temperature in terms of Peng Robinson parameter a and other actual and critical parameters

Go

Created Reduced Temperature in terms of Peng Robinson parameter a and other actual and reduced parameters

Go

Created Reduced Temperature in terms of Peng Robinson parameter b and other actual and critical parameters

Go

Created Reduced Temperature in terms of Peng Robinson parameter b and other actual and reduced parameters

Go

Created Reduced Temperature using Peng Robinson equation in terms of critical and actual parameters

Go

Created Reduced Temperature using Peng Robinson equation in terms of reduced and critical parameters

Go

Created Temperature of real gas using Peng Robinson equation

Go

Created Temperature of real gas using Peng Robinson equation in terms of reduced and critical parameters

Go

Verified Bond energy of elements A and B

Go

Verified Crystal radius

Go

Verified Distance between two metal atoms

Go

Verified Electronegativity of element A in kcal per mole

Go

Verified Electronegativity of element A in KJ mole

Go

Verified Electronegativity of element B in kcal per mole

Go

Verified Electronegativity of element B in KJ mole

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

14 More Periodic Table and Periodicity Calculators

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Verified Equilibrium constant for reverse reaction

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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 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 an 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 constants

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Verified Forward rate constant in an 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 an enzymatic reaction mechanism

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Created Actual molar volume of real gas using critical and reduced volume

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Created Actual pressure of real gas using critical and reduced pressure

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Created Actual temperature of real gas using critical and reduced temperature

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Created Actual volume of real gas using critical and reduced volume

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Created Critical molar volume of real gas using actual and reduced volume

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Created Critical pressure of real gas using actual and reduced pressure

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Created Critical saturation vapor pressure using Acentric factor

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Created Critical saturation vapor pressure using actual and reduced saturation vapor pressure

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Created Critical temperature of real gas using actual and reduced temperature

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Created Critical volume of real gas using actual and reduced volume

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Created Reduced molar volume of real gas using actual and critical volume

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Created Reduced pressure of real gas using actual and critical pressure

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Created Reduced saturation vapor pressure using Acentric factor

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Created Reduced saturation vapor pressure using actual and critical saturation vapor pressure

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Created Reduced temperature of real gas using actual and critical temperature

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Created Reduced volume of real gas using actual and critical volume

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Created Saturation vapor pressure using Acentric factor

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Created Saturation vapor pressure using reduced and critical saturation vapor pressure

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Created Actual Molar Volume using Redlich Kwong equation in terms of a and b

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Created Actual of Molar Volume real gas using Reduced Redlich Kwong equation

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Created Actual Pressure of real gas using Redlich Kwong equation in terms of only a

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Created Actual Pressure of real gas using Redlich Kwong equation in terms of only 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 in terms of a and b

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Created Actual Temperature of real gas using Redlich Kwong equation in terms of only a

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Created Actual Temperature of real gas using Redlich Kwong equation in terms of only 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 in terms of a and b

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Created Critical Molar Volume of real gas using Redlich Kwong equation in terms of 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 in terms of a and b

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Created Critical Pressure of real gas using Redlich Kwong equation in terms of only a

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Created Critical Pressure of real gas using Redlich Kwong equation in terms of only b

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Created Critical Pressure of real gas using Reduced Redlich Kwong equation

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Created Critical Temperature of real gas using Redlich Kwong equation in terms of a and b

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Created Critical Temperature of real gas using Redlich Kwong equation in terms of only a

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Created Critical Temperature of real gas using Redlich Kwong equation in terms of only b

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Created Critical Temperature 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 Redlich Kwong parameter a at critical point

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Created Redlich Kwong parameter a in terms of Pressure, Temperature and Molar Volume of real gas

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Created Redlich Kwong parameter a in terms of Reduced and actual pressure

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Created Redlich Kwong parameter b at critical point

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Created Redlich Kwong parameter b in terms of Pressure, Temperature and Molar Volume of real gas

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Created Redlich Kwong parameter b in terms of reduced and actual pressure

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Created Reduced Molar Volume of real gas using Reduced Redlich Kwong equation

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Created Reduced Molar Volume using Redlich Kwong equation in terms of a and b

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Created Reduced Pressure of real gas using Redlich Kwong equation in terms of only a

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Created Reduced Pressure of real gas using Redlich Kwong equation in terms of only 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 in terms of a and b

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Created Reduced Temperature of real gas using Redlich Kwong equation in terms of only a

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Created Reduced Temperature of real gas using Redlich Kwong equation in terms of only b

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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 in terms of a and b

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Created Temperature of real gas using Redlich Kwong equation

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Verified Equilibrium constant in terms of mole fraction given degree of dissociation

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19 More Relation between equilibrium constant and degree of dissociation Calculators

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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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Verified Initial vapour density using concentration of reaction

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Verified Initial vapour density when number of moles of products at equilibrium is half

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Verified Molecular weight abnormal given vapour density at equilibrium

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Verified Vapour density at equilibrium given molecular weight abnormal

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Verified Vapour density at equilibrium using conc 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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Verified Volume of equilibrium mixture of substances A and B

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32 More Relation between vapour density and degree of dissociation Calculators

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Created Molality using Relative Lowering Of Vapour Pressure

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Created Mole Fraction of solute in terms of Vapour Pressure

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Created Mole Fraction of solvent in terms of Vapour Pressure

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Created Molecular Mass of solute using Relative Lowering Of Vapour Pressure

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Created Molecular Mass of solvent using Relative Lowering Of Vapour Pressure

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Created Moles of solute in dilute solution using Relative Lowering Of Vapour Pressure

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Created Moles of solvent in dilute solution using Relative Lowering Of Vapour Pressure

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Created Ostwald-Walker Dynamic Method for Relative Lowering Of Vapour Pressure

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Created Relative Lowering Of Vapour Pressure

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Created Relative Lowering Of Vapour Pressure in terms of Molecular mass and Molality

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Created Relative Lowering Of Vapour Pressure in terms of number of moles for a concentrated solution

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Created Relative Lowering Of Vapour Pressure in terms of number of moles for a dilute solution

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Created Relative Lowering Of Vapour Pressure in terms of weight and molecular mass of solute and solvent

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Created Van't Hoff Factor for Relative Lowering Of Vapour Pressure in terms of Molecular mass and Molality

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Created Van't Hoff Factor for Relative Lowering Of Vapour Pressure in terms of number of moles

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Created Van't Hoff Relative Lowering Of Vapour Pressure in terms of Molecular mass and Molality

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Created Van't Hoff Relative Lowering Of Vapour Pressure in terms of number of moles

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Created Weight of solute using Relative Lowering Of Vapour Pressure

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Created Weight of solvent using Relative Lowering Of Vapour Pressure

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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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Verified Partition coefficient of solute 1 given relative retention

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Verified Partition coefficient of solute 2 given relative retention

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Verified Relative retention given capacity factor of two components

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Verified Relative retention given partition coefficient of two components

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3 More Relative retention Calculators

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Verified Area of cross-section given Resistance and Resistivity

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Verified Distance between electrode given resistance and resistivity

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Verified Resistance given conductance

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Verified Resistance given distance between electrode and area of cross-section of electrode

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Verified Resistivity given specific conductance

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4 More Resistance and Resistivity Calculators

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Verified Adjusted retention time given retention time

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Verified Average width of peak given resolution and change in retention time

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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 Half width of peak given number of theoretical plates and retention time

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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 Resolution of two peaks given change in retention time

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Verified Retention time given adjusted retention time

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Verified Retention time given number of theoretical plate and half width of peak

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Verified Retention time given number of theoretical plates and standard deviation

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Verified Retention time given number of theoretical plates and width of peak

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Verified Retention time given retention volume

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Verified Width of peak given number of theoretical plates and retention time

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2 More Retention time Calculators

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Verified Average width of peak given resolution and change in retention volume

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Verified Capacity factor given retention volume and unretained volume

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Verified Change in retention volume given resolution and average width of peak

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Verified Flow rate given retention volume and time

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Verified Half of average width of peaks given resolution and change in retention volume

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Verified Resolution of two peaks given the change in retention volume

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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 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 Covalent Ionic Resonance Energy

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Created Covalent Ionic Resonance Energy using Bond Energies

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Created Covalent Ionic Resonance Energy using Pauling's Electronegativity

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Created Covalent radius given Pauling's Electronegativity

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Created Effective Nuclear Charge given Pauling's Electronegativity

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Created Electron Affinity of an element using Mulliken's Electronegativity

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Created Electron Affinity of an element using Pauling's Electronegativity

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Created Ionization Energy of an element using Mulliken's Electronegativity

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Created Ionization Energy of an element using Pauling's Electronegativity

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Created Mulliken's Electronegativity from Allred Rochow's Electronegativity

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Created Mulliken's Electronegativity from Pauling's Electronegativity

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Created Mulliken's Electronegativity given Effective Nuclear Charge and Covalent radius

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Created Mulliken's Electronegativity in terms of bond energies

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Created Mulliken's Electronegativity of an element

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Created Pauling's Electronegativity from Allred Rochow's Electronegativity

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Created Pauling's Electronegativity from Mulliken's Electronegativity

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Created Pauling's Electronegativity given Effective Nuclear Charge and Covalent radius

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Created Pauling's Electronegativity given IE and EA

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Created Pauling's Electronegativity in terms of bond energies

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Created Pauling's Electronegativity in terms of individual electronegativities

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Created 1D Lattice Direction for Lattice Points

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Created 2D Lattice Direction for Lattice Points

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Created 3D Lattice Direction for Lattice Points

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Created 3D Lattice Direction for points in space which are not Lattice Points

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Created 3D Lattice Direction for points in space which are not Lattice Points with respect to lattice points

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Created Edge Length using Interplanar Distance of Cubic Crystal

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Created Energy per impurity

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Created Energy per vacancy

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Created Fraction of impurity in lattice

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Created Fraction of impurity in lattice in terms of Energy

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Created Fraction of Vacancy in lattice

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Created Fraction of Vacancy in lattice in terms of Energy

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Created Miller index along X-axis using Weiss Indices

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Created Miller index along Y-axis using Weiss Indices

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Created Miller index along Z-axis using Weiss Indices

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Created Number of lattice containing impurities

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Created Number of vacant lattice

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Created Weiss Index along X-axis using Miller Indices

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Created Weiss Index along Y-axis using Miller Indices

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Created Weiss Index along Z-axis using Miller Indices

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10 More Solid State Chemistry Calculators

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Created Depression in freezing point in terms of Elevation in Boiling Point

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Created Depression in freezing point in terms of Osmotic Pressure

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Created Depression in freezing point in terms of Relative Lowering of Vapour Pressure

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Created Depression in freezing point in terms of Vapour Pressure

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Created Elevation in Boiling Point in terms of Depression in freezing point

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Created Elevation in Boiling Point in terms of Osmotic Pressure

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Created Elevation in Boiling Point in terms of Relative Lowering of Vapour Pressure

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Created Elevation in Boiling Point in terms of Vapour Pressure

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Created Osmotic Pressure in terms of Depression in freezing point

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Created Osmotic Pressure in terms of Elevation in Boiling Point

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Created Osmotic Pressure in terms of Relative Lowering of Vapour Pressure

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Created Osmotic Pressure in terms of Vapour Pressure

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Created Relative Lowering of Vapour Pressure in terms of Depression in freezing point

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Created Relative Lowering of Vapour Pressure in terms of Elevation in Boiling Point

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Created Relative Lowering of Vapour Pressure in terms of Osmotic Pressure

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Created Adiabatic Index of Real Gas

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Created Adiabatic Index of Real Gas in terms of Heat Capacity at constant Pressure

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Created Adiabatic Index of Real Gas in terms of Heat Capacity at constant Volume

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Created Coefficient of thermal expansion of real gas

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Created Coefficient of thermal expansion of real gas given difference between Cp and Cv

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Created Difference between Cp and Cv of real gas

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Created Heat Capacity at constant Pressure of real gas

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Created Heat Capacity at constant Volume of real gas

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Created Isothermal compressibility of real gas

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Created Isothermal compressibility of real gas given difference between Cp and Cv

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Created Specific Volume of real gas given difference between Cp and Cv

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Created Specific Volume of real gas in terms of Heat Capacities

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Created Temperature of real gas given difference between Cp and Cv

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Created Temperature of real gas in terms of Heat Capacities

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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 products

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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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9 More Stark-Einstein law 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 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 in terms of 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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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 constants

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Verified Enzyme substrate complex concentration in the 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 the presence of uncompetitive inhibitor

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Verified Enzyme substrate inhibitor concentration in the 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 the presence of uncompetitive inhibitor

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Verified Inhibitor concentration in the presence of uncompetitive inhibitor

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Verified Initial reaction rate in the presence of uncompetitive inhibitor

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Verified Maximum reaction rate in the presence of uncompetitive inhibitor

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Verified Michaelis constant in the presence of uncompetitive inhibitor

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Verified Substrate concentration in the presence of uncompetitive inhibitor

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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 the particle-particle pair interaction using Van der Waals pair potential

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Created Concentration using Number density

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Created Distance between the surfaces using Center-to-center distance

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Created Distance between the surfaces using Potential Energy in the limit of close-approach

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Created Distance between the surfaces using Van der Waals force between two spheres

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Created Distance between the surfaces using Van der Waals pair potential

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Created Hamaker coefficient

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Created Hamaker coefficient using Potential Energy in the limit of close-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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Created Mass density in terms of Number density

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Created Mass of single atom

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Created Molar mass in terms of Number and mass density

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Created Number density in terms of concentration

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Created Number density in terms of mass density

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Created Number density of particle 1 using Hamaker coefficient

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Created Number density of particle 2 using Hamaker coefficient

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Created Potential Energy in the limit of close-approach

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Created Radius of spherical body 1 using Center-to-center distance

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Created Radius of spherical body 1 using Potential Energy in the limit of close-approach

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Created Radius of spherical body 1 using Van der Waals force between two spheres

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Created Radius of spherical body 2 using Center-to-center distance

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Created Radius of spherical body 2 using Potential Energy in the limit of close-approach

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Created Radius of spherical body 2 using 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 2 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 in terms of Van't Hoff Factor

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Created Degree of Dissociation in terms of 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 in terms of experimental and theoretical osmotic pressure

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Created Van't Hoff factor in terms of colligative property

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Created Van't Hoff Factor in terms of molality

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Created Van't Hoff factor in terms of Molar Mass

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Created Van't Hoff Factor in terms of number of particles

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Created Van't Hoff factor using Degree of Association

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Created Van't Hoff factor using Degree of Dissociation

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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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14 More Vapor Liquid Equilibrium 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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Verified Capacity factor given partition coefficient and volume of mobile and stationary phase

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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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3 More Volume of mobile and stationary phase Calculators

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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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Created Actual Molar Volume of real gas in terms of Wohl parameter a and actual and reduced parameters

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Created Actual Molar Volume of real gas in terms of Wohl parameter a and reduced and critical parameters

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Created Actual Molar Volume of real gas in terms of Wohl parameter b and actual and reduced parameters

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Created Actual Molar Volume of real gas in terms of Wohl parameter b and reduced and critical parameters

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Created Actual Molar Volume of real gas in terms of Wohl parameter c and actual and reduced parameters

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Created Actual Molar Volume of real gas in terms of Wohl parameter c and reduced and critical parameters

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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 in terms of Wohl parameter a and reduced and actual parameters

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Created Actual Pressure of real gas in terms of Wohl parameter a and reduced and critical parameters

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Created Actual Pressure of real gas in terms of Wohl parameter b and reduced and actual parameters

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Created Actual Pressure of real gas in terms of Wohl parameter b and reduced and critical parameters

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Created Actual Pressure of real gas in terms of Wohl parameter c and reduced and actual parameters

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Created Actual Pressure of real gas in terms of Wohl parameter c and reduced and critical parameters

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Created Actual Pressure of real gas using Reduced Wohl equation in terms of actual and critical parameters

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Created Actual Pressure of real gas using Reduced Wohl equation in terms of 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 in terms of Wohl parameter a and reduced and actual parameters

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Created Actual Temperature of real gas in terms of Wohl parameter a and reduced and critical parameters

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Created Actual Temperature of real gas in terms of Wohl parameter b and reduced and actual parameters

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Created Actual Temperature of real gas in terms of Wohl parameter b and reduced and critical parameters

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Created Actual Temperature of real gas in terms of Wohl parameter c and reduced and actual parameters

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Created Actual Temperature of real gas in terms of 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 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 Wohl equation in terms of Wohl parameter a

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Created Critical Molar Volume of real gas using Wohl equation in terms of Wohl parameter b

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Created Critical Molar Volume of real gas using Wohl equation in terms of Wohl parameter c

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Created Critical Molar Volume of Wohl's real gas using other actual and reduced parameters

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Created Critical Molar Volume of Wohl's real gas using other critical parameters

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Created Critical Pressure of real gas in terms of Wohl parameter a and other actual and reduced parameters

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Created Critical Pressure of real gas in terms of Wohl parameter b and other actual and reduced parameters

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Created Critical Pressure of real gas in terms of Wohl parameter c and other actual and reduced parameters

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Created Critical Pressure of real gas using Reduced Wohl equation in terms of actual and critical parameters

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Created Critical Pressure of real gas using Reduced Wohl equation in terms of actual and reduced parameters

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Created Critical Pressure of real gas using Wohl equation in terms of reduced and actual parameters

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Created Critical Pressure of real gas using Wohl equation in terms of reduced and critical parameters

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Created Critical Pressure of real gas using Wohl equation in terms of Wohl parameter a

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Created Critical Pressure of real gas using Wohl equation in terms of Wohl parameter b

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Created Critical Pressure of real gas using Wohl equation in terms of 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 Critical Temperature of real gas for Wohl parameter a and other actual and reduced parameters

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Created Critical Temperature of real gas using Wohl equation in terms of reduced and actual parameters

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Created Critical Temperature of real gas using Wohl equation in terms of reduced and critical parameters

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Created Critical Temperature of real gas using Wohl equation in terms of Wohl parameter a

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Created Critical Temperature of real gas using Wohl equation in terms of Wohl parameter b

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Created Critical Temperature of real gas using Wohl equation in terms of Wohl parameter c

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Created Critical Temperature of real gas using Wohl parameter b and other actual and reduced parameters

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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 using other actual and reduced parameters

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Created Critical Temperature of Wohl's real gas using other critical parameters

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Created Pressure of real gas using Wohl equation

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Created Pressure of real gas using Wohl equation in terms of reduced and critical parameters

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Created Reduced Molar Volume of real gas in terms of Wohl parameter a and actual and critical parameters

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Created Reduced Molar Volume of real gas in terms of Wohl parameter a and actual and reduced parameters

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Created Reduced Molar Volume of real gas in terms of Wohl parameter b and actual and critical parameters

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Created Reduced Molar Volume of real gas in terms of Wohl parameter b and actual and reduced parameters

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Created Reduced Molar Volume of real gas in terms of Wohl parameter c and actual and critical parameters

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Created Reduced Molar Volume of real gas in terms of Wohl parameter c and actual and reduced parameters

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Created Reduced Molar Volume of Wohl's real gas using other actual and critical parameters

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Created Reduced Molar Volume of Wohl's real gas using other actual and reduced parameters

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Created Reduced Pressure of real gas in terms of Wohl parameter a and actual and critical parameters

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Created Reduced Pressure of real gas in terms of Wohl parameter b and actual and critical parameters

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Created Reduced Pressure of real gas in terms of Wohl parameter b and actual and reduced parameters

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Created Reduced Pressure of real gas in terms of Wohl parameter c and actual and critical parameters

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Created Reduced Pressure of real gas in terms of Wohl parameter c and actual and reduced parameters

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Created Reduced Pressure of real gas using Reduced Wohl equation in terms of actual and critical parameters

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Created Reduced Pressure of real gas using Reduced Wohl equation in terms of reduced parameters

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Created Reduced Pressure of real gas using Wohl equation in terms of critical and actual parameters

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Created Reduced Pressure of real gas using Wohl equation in terms of 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 Reduced Temperature of real gas in terms of Wohl parameter a and actual and critical parameters

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Created Reduced Temperature of real gas in terms of Wohl parameter a and actual and reduced parameters

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Created Reduced Temperature of real gas in terms of Wohl parameter b and actual and critical parameters

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Created Reduced Temperature of real gas in terms of Wohl parameter b and actual and reduced parameters

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Created Reduced Temperature of real gas in terms of Wohl parameter c and actual and critical parameters

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Created Reduced Temperature of real gas in terms of Wohl parameter c and actual and reduced parameters

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Created Reduced Temperature of real gas using Wohl equation in terms of critical and actual parameters

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Created Reduced Temperature of real gas using Wohl equation in terms of reduced and critical parameters

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Created Reduced Temperature of Wohl's real gas using other actual and critical parameters

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Created Reduced Temperature of Wohl's real gas using other actual and reduced 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 in terms of reduced and critical parameters

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Created Wohl parameter a of real gas in terms of 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 in terms of actual and critical parameters

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Created Wohl parameter a of real gas using Wohl equation in terms of actual and reduced parameters

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Created Wohl parameter a of real gas using Wohl equation in terms of critical parameters

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Created Wohl parameter a of real gas using Wohl equation in terms of reduced and critical parameters

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Created Wohl parameter b of real gas in terms of actual and reduced molar volume

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Created Wohl parameter b of real gas in terms of 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 in terms of actual and critical parameters

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Created Wohl parameter b of real gas using Wohl equation in terms of actual and reduced parameters

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Created Wohl parameter b of real gas using Wohl equation in terms of critical molar volume

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Created Wohl parameter b of real gas using Wohl equation in terms of critical temperature and pressure

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Created Wohl parameter b of real gas using Wohl equation in terms of reduced and critical parameters

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Created Wohl parameter c of real gas in terms of 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 in terms of actual and critical parameters

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Created Wohl parameter c of real gas using Wohl equation in terms of actual and reduced parameters

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Created Wohl parameter c of real gas using Wohl equation in terms of critical parameters

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Created Wohl parameter c of real gas using Wohl equation in terms of reduced and critical parameters

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List of Calculators by Prerana Bakli