Largest Charge Seperation in Collision Calculator

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✖Reaction Cross Section is a measure of the effective size of the molecules as determined propensity (tendency) to react, at a given collision energy.ⓘ Reaction Cross Section [σ_R]

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✖Largest Charge Seperation is the maximum seperation in between positive and negative charges in a particle.ⓘ Largest Charge Seperation in Collision [R_x]

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Largest Charge Seperation in Collision

Formula

`"R"_{"x"} = sqrt("σ"_{"R"}/pi)`

Example

`"1.261566m"=sqrt("5m²"/pi)`

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Largest Charge Seperation in Collision Solution

STEP 0: Pre-Calculation Summary

Formula Used

Largest Charge Seperation = sqrt(Reaction Cross Section/pi)
R_x = sqrt(σ_R/pi)
This formula uses 1 Constants, 1 Functions, 2 Variables

Constants Used

pi - Archimedes' constant Value Taken As 3.14159265358979323846264338327950288

Functions Used

sqrt - A square root function is a function that takes a non-negative number as an input and returns the square root of the given input number., sqrt(Number)

Variables Used

Largest Charge Seperation - (Measured in Meter) - Largest Charge Seperation is the maximum seperation in between positive and negative charges in a particle.
Reaction Cross Section - (Measured in Square Meter) - Reaction Cross Section is a measure of the effective size of the molecules as determined propensity (tendency) to react, at a given collision energy.

STEP 1: Convert Input(s) to Base Unit

Reaction Cross Section: 5 Square Meter --> 5 Square Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

R_x = sqrt(σ_R/pi) --> sqrt(5/pi)

Evaluating ... ...

R_x = 1.26156626101008

STEP 3: Convert Result to Output's Unit

1.26156626101008 Meter --> No Conversion Required

FINAL ANSWER

1.26156626101008 ≈ 1.261566 Meter <-- Largest Charge Seperation

(Calculation completed in 00.004 seconds)

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National University of Judicial Science (NUJS), Kolkata

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< 19 Molecular Reaction Dynamics Calculators

Collision Cross Section in Ideal Gas

Go Collisional Cross Section = (Collision Frequency/Number Density for A Molecules*Number Density for B Molecules)*sqrt(pi*Reduced Mass of Reactants A and B/8*[BoltZ]*Temperature in terms of Molecular Dynamics)

Collision Frequency in Ideal Gas

Go Collision Frequency = Number Density for A Molecules*Number Density for B Molecules*Collisional Cross Section*sqrt((8*[BoltZ]*Time in terms of Ideal Gas/pi*Reduced Mass of Reactants A and B))

Reduced Mass of Reactants using Collision Frequency

Go Reduced Mass of Reactants A and B = ((Number Density for A Molecules*Number Density for B Molecules*Collisional Cross Section/Collision Frequency)^2)*(8*[BoltZ]*Temperature in terms of Molecular Dynamics/pi)

Number of Collisions per Second in Equal Size Particles

Go Number of Collisions per Second = ((8*[BoltZ]*Temperature in terms of Molecular Dynamics*Concentration of Equal Size Particle in Solution)/(3*Viscosity of Fluid in Quantum))

Concentration of Equal Size Particle in Solution using Collision Rate

Go Concentration of Equal Size Particle in Solution = (3*Viscosity of Fluid in Quantum*Number of Collisions per Second)/(8*[BoltZ]*Temperature in terms of Molecular Dynamics)

Temperature of Molecular Particle using Collision Rate

Go Temperature in terms of Molecular Dynamics = (3*Viscosity of Fluid in Quantum*Number of Collisions per Second)/(8*[BoltZ]*Concentration of Equal Size Particle in Solution)

Viscosity of Solution using Collision Rate

Go Viscosity of Fluid in Quantum = (8*[BoltZ]*Temperature in terms of Molecular Dynamics*Concentration of Equal Size Particle in Solution)/(3*Number of Collisions per Second)

Number Density for A Molecules using Collision Rate Constant

Go Number Density for A Molecules = Collision Frequency/(Velocity of Beam Molecules*Number Density for B Molecules*Cross Sectional Area for Quantum)

Cross Sectional Area using Rate of Molecular Collisions

Go Cross Sectional Area for Quantum = Collision Frequency/(Velocity of Beam Molecules*Number Density for B Molecules*Number Density for A Molecules)

Number of Bimolecular Collision per Unit Time per Unit Volume

Go Collision Frequency = Number Density for A Molecules*Number Density for B Molecules*Velocity of Beam Molecules*Cross Sectional Area for Quantum

Reduced Mass of Reactants A and B

Go Reduced Mass of Reactants A and B = (Mass of Reactant B*Mass of Reactant B)/(Mass of Reactant A+Mass of Reactant B)

Miss Distance between Particles in Collision

Go Miss Distance = sqrt(((Interparticle Distance Vector^2)*Centrifugal Energy)/Total Energy Before Collision)

Interparticle Distance Vector in Molecular Reaction Dynamics

Go Interparticle Distance Vector = sqrt(Total Energy Before Collision*(Miss Distance^2)/Centrifugal Energy)

Centrifugal Energy in Collision

Go Centrifugal Energy = Total Energy Before Collision*(Miss Distance^2)/(Interparticle Distance Vector^2)

Total Energy before Collision

Go Total Energy Before Collision = Centrifugal Energy*(Interparticle Distance Vector^2)/(Miss Distance^2)

Vibrational Frequency given Boltzmann's Constant

Go Vibrational Frequency = ([BoltZ]*Temperature in terms of Molecular Dynamics)/[hP]

Collisional Cross Section

Go Collisional Cross Section = pi*((Radius of Molecule A*Radius of Molecule B)^2)

Largest Charge Seperation in Collision

Go Largest Charge Seperation = sqrt(Reaction Cross Section/pi)

Reaction Cross Section in Collision

Go Reaction Cross Section = pi*(Largest Charge Seperation^2)

Largest Charge Seperation in Collision Formula

Largest Charge Seperation = sqrt(Reaction Cross Section/pi)
R_x = sqrt(σ_R/pi)

What is Collision Theory?

Collision theory states that when suitable particles of the reactant hit each other with correct orientation, only a certain amount of collisions result in a perceptible or notable change; these successful changes are called successful collisions. The successful collisions must have enough energy, also known as activation energy, at the moment of impact to break the pre-existing bonds and form all new bonds.

How to Calculate Largest Charge Seperation in Collision?

Largest Charge Seperation in Collision calculator uses Largest Charge Seperation = sqrt(Reaction Cross Section/pi) to calculate the Largest Charge Seperation, The Largest Charge Seperation in Collision formula is defined as the largest seperation distance between particles at which the charge separation can take place on energetic grounds. Largest Charge Seperation is denoted by R_x symbol.

How to calculate Largest Charge Seperation in Collision using this online calculator? To use this online calculator for Largest Charge Seperation in Collision, enter Reaction Cross Section (σ_R) and hit the calculate button. Here is how the Largest Charge Seperation in Collision calculation can be explained with given input values -> 1.261566 = sqrt(5/pi).

FAQ

What is Largest Charge Seperation in Collision?

The Largest Charge Seperation in Collision formula is defined as the largest seperation distance between particles at which the charge separation can take place on energetic grounds and is represented as R_x = sqrt(σ_R/pi) or Largest Charge Seperation = sqrt(Reaction Cross Section/pi). Reaction Cross Section is a measure of the effective size of the molecules as determined propensity (tendency) to react, at a given collision energy.

How to calculate Largest Charge Seperation in Collision?

The Largest Charge Seperation in Collision formula is defined as the largest seperation distance between particles at which the charge separation can take place on energetic grounds is calculated using Largest Charge Seperation = sqrt(Reaction Cross Section/pi). To calculate Largest Charge Seperation in Collision, you need Reaction Cross Section (σ_R). With our tool, you need to enter the respective value for Reaction Cross Section and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

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