Temperature in Arrhenius Equation for Second Order Reaction Calculator

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Second Order Reaction

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✖Activation Energy is the minimum amount of energy that is required to activate atoms or molecules to a condition in which they can undergo chemical transformation.ⓘ Activation Energy [E_a1]			+10% -10%
✖Frequency Factor from Arrhenius Eqn for 2nd Order is also known as the pre-exponential factor and it describes the frequency of reaction and correct molecular orientation.ⓘ Frequency Factor from Arrhenius Eqn for 2nd Order [A_{factor-secondorder}]			+10% -10%
✖The Rate Constant for Second Order Reaction is defined as the average rate of the reaction per concentration of the reactant having power raised to 2.ⓘ Rate Constant for Second Order Reaction [K_second]			+10% -10%

✖Temperature in Arrhenius Eq for 2nd Order Reaction is the degree or intensity of heat present in a substance or object.ⓘ Temperature in Arrhenius Equation for Second Order Reaction [Temp_SecondOrder]

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Temperature in Arrhenius Equation for Second Order Reaction

Formula

`"Temp"_{"SecondOrder"} = "E"_{"a1"}/"[R]"*(ln("A"_{"factor-secondorder"}/"K"_{"second"}))`

Example

`"6.629941K"="197.3778J/mol"/"[R]"*(ln("0.674313L/(mol*s)"/"0.51L/(mol*s)"))`

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Temperature in Arrhenius Equation for Second Order Reaction Solution

STEP 0: Pre-Calculation Summary

Formula Used

Temperature in Arrhenius Eq for 2nd Order Reaction = Activation Energy/[R]*(ln(Frequency Factor from Arrhenius Eqn for 2nd Order/Rate Constant for Second Order Reaction))
Temp_SecondOrder = E_a1/[R]*(ln(A_{factor-secondorder}/K_second))
This formula uses 1 Constants, 1 Functions, 4 Variables

Constants Used

[R] - Universal gas constant Value Taken As 8.31446261815324

Functions Used

ln - The natural logarithm, also known as the logarithm to the base e, is the inverse function of the natural exponential function., ln(Number)

Variables Used

Temperature in Arrhenius Eq for 2nd Order Reaction - (Measured in Kelvin) - Temperature in Arrhenius Eq for 2nd Order Reaction is the degree or intensity of heat present in a substance or object.
Activation Energy - (Measured in Joule Per Mole) - Activation Energy is the minimum amount of energy that is required to activate atoms or molecules to a condition in which they can undergo chemical transformation.
Frequency Factor from Arrhenius Eqn for 2nd Order - (Measured in Cubic Meter per Mole Second) - Frequency Factor from Arrhenius Eqn for 2nd Order is also known as the pre-exponential factor and it describes the frequency of reaction and correct molecular orientation.
Rate Constant for Second Order Reaction - (Measured in Cubic Meter per Mole Second) - The Rate Constant for Second Order Reaction is defined as the average rate of the reaction per concentration of the reactant having power raised to 2.

STEP 1: Convert Input(s) to Base Unit

Activation Energy: 197.3778 Joule Per Mole --> 197.3778 Joule Per Mole No Conversion Required
Frequency Factor from Arrhenius Eqn for 2nd Order: 0.674313 Liter per Mole Second --> 0.000674313 Cubic Meter per Mole Second (Check conversion here)
Rate Constant for Second Order Reaction: 0.51 Liter per Mole Second --> 0.00051 Cubic Meter per Mole Second (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

Temp_SecondOrder = E_a1/[R]*(ln(A_{factor-secondorder}/K_second)) --> 197.3778/[R]*(ln(0.000674313/0.00051))

Evaluating ... ...

Temp_SecondOrder = 6.62994094895999

STEP 3: Convert Result to Output's Unit

6.62994094895999 Kelvin --> No Conversion Required

FINAL ANSWER

6.62994094895999 ≈ 6.629941 Kelvin <-- Temperature in Arrhenius Eq for 2nd Order Reaction

(Calculation completed in 00.004 seconds)

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Created by Prashant Singh

K J Somaiya College of science (K J Somaiya), Mumbai

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National Institute Of Technology (NIT), Surathkal

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< 15 Second Order Reaction Calculators

Time of Completion for different Products for Second Order Reaction

Go Time for completion = 2.303/(Rate Constant for Second Order Reaction*(Initial Reactant A Concentration-Initial Reactant B Concentration))*log10(Initial Reactant B Concentration*(Concentration at Time t of Reactant A))/(Initial Reactant A Concentration*(Concentration at Time t of Reactant B))

Rate Constant for different Products for Second Order Reaction

Go Rate Constant for First Order Reaction = 2.303/(Time for completion*(Initial Reactant A Concentration-Initial Reactant B Concentration))*log10(Initial Reactant B Concentration*(Concentration at Time t of Reactant A))/(Initial Reactant A Concentration*(Concentration at Time t of Reactant B))

Temperature in Arrhenius Equation for Second Order Reaction

Go Temperature in Arrhenius Eq for 2nd Order Reaction = Activation Energy/[R]*(ln(Frequency Factor from Arrhenius Eqn for 2nd Order/Rate Constant for Second Order Reaction))

Activation Energy for Second Order Reaction

Go Energy of Activation = [R]*Temperature_Kinetics*(ln(Frequency Factor from Arrhenius Equation)-ln(Rate Constant for Second Order Reaction))

Time of Completion for Same product for Second Order Reaction

Go Time for completion = 1/(Concentration at time t for second order*Rate Constant for Second Order Reaction)-1/(Initial Concentration for Second Order Reaction*Rate Constant for Second Order Reaction)

Rate Constant for Second Order Reaction from Arrhenius Equation

Go Rate Constant for Second Order Reaction = Frequency Factor from Arrhenius Eqn for 2nd Order*exp(-Activation Energy/([R]*Temperature for Second Order Reaction))

Arrhenius Constant for Second Order Reaction

Go Frequency Factor from Arrhenius Eqn for 2nd Order = Rate Constant for Second Order Reaction/exp(-Activation Energy/([R]*Temperature for Second Order Reaction))

Rate Constant for Same Product for Second Order Reaction

Go Rate Constant for Second Order Reaction = 1/(Concentration at time t for second order*Time for completion)-1/(Initial Concentration for Second Order Reaction*Time for completion)

Time for Completion for Same Product by Titration Method for Second Order Reaction

Go Time for completion = (1/(Volume at Time t*Rate Constant for Second Order Reaction))-(1/(Initial Reactant Volume*Rate Constant for Second Order Reaction))

Rate Constant for same product by Titration method for Second Order reaction

Go Rate Constant for Second Order Reaction = (1/(Volume at Time t*Time for completion))-(1/(Initial Reactant Volume*Time for completion))

Quarter life of Second Order Reaction

Go Quarter Life of Second Order Reaction = 1/(Initial Concentration*Rate Constant for Second Order Reaction)

Half Life of Second Order Reaction

Go Half Life of Second Order Reaction = 1/Reactant Concentration*Rate Constant for Second Order Reaction

Order of Bimolecular Reaction with respect to Reactant A

Go Power Raised to Reactant 1 = Overall Order-Power Raised to Reactant 2

Order of Bimolecular Reaction with respect to Reactant B

Go Power Raised to Reactant 2 = Overall Order-Power Raised to Reactant 1

Overall Order of Bimolecular Reaction

Go Overall Order = Power Raised to Reactant 1+Power Raised to Reactant 2

< 11 Temperature Dependency from Arrhenius' Law Calculators

Activation Energy using Rate Constant at Two Different Temperatures

Go Activation Energy Rate Constant = [R]*ln(Rate Constant at Temperature 2/Rate Constant at Temperature 1)*Reaction 1 Temperature*Reaction 2 Temperature/(Reaction 2 Temperature-Reaction 1 Temperature)

Activation Energy using Reaction Rate at Two Different Temperatures

Go Activation Energy = [R]*ln(Reaction Rate 2/Reaction Rate 1)*Reaction 1 Temperature*Reaction 2 Temperature/(Reaction 2 Temperature-Reaction 1 Temperature)

Temperature in Arrhenius Equation for First Order Reaction

Go Temperature in Arrhenius Eq for 1st Order Reaction = modulus(Activation Energy/[R]*(ln(Frequency Factor from Arrhenius Eqn for 1st Order/Rate Constant for First Order Reaction)))

Temperature in Arrhenius Equation for Zero Order Reaction

Go Temperature in Arrhenius Eq Zero Order Reaction = modulus(Activation Energy/[R]*(ln(Frequency Factor from Arrhenius Eqn for Zero Order/Rate Constant for Zero Order Reaction)))

Temperature in Arrhenius Equation for Second Order Reaction

Go Temperature in Arrhenius Eq for 2nd Order Reaction = Activation Energy/[R]*(ln(Frequency Factor from Arrhenius Eqn for 2nd Order/Rate Constant for Second Order Reaction))

Rate Constant for Second Order Reaction from Arrhenius Equation

Go Rate Constant for Second Order Reaction = Frequency Factor from Arrhenius Eqn for 2nd Order*exp(-Activation Energy/([R]*Temperature for Second Order Reaction))

Arrhenius Constant for Second Order Reaction

Go Frequency Factor from Arrhenius Eqn for 2nd Order = Rate Constant for Second Order Reaction/exp(-Activation Energy/([R]*Temperature for Second Order Reaction))

Rate Constant for First Order Reaction from Arrhenius Equation

Go Rate Constant for First Order Reaction = Frequency Factor from Arrhenius Eqn for 1st Order*exp(-Activation Energy/([R]*Temperature for First Order Reaction))

Arrhenius Constant for First Order Reaction

Go Frequency Factor from Arrhenius Eqn for 1st Order = Rate Constant for First Order Reaction/exp(-Activation Energy/([R]*Temperature for First Order Reaction))

Rate Constant for Zero Order Reaction from Arrhenius Equation

Go Rate Constant for Zero Order Reaction = Frequency Factor from Arrhenius Eqn for Zero Order*exp(-Activation Energy/([R]*Temperature for Zero Order Reaction))

Arrhenius Constant for Zero Order Reaction

Go Frequency Factor from Arrhenius Eqn for Zero Order = Rate Constant for Zero Order Reaction/exp(-Activation Energy/([R]*Temperature for Zero Order Reaction))

< 20 Basics of Reactor Design and Temperature Dependency from Arrhenius Law Calculators

Key Reactant Conversion with Varying Density,Temperature and Total Pressure

Go Key-Reactant Conversion = (1-((Key-Reactant Concentration/Initial Key-Reactant Concentration)*((Temperature*Initial Total Pressure)/(Initial Temperature*Total Pressure))))/(1+Fractional Volume Change*((Key-Reactant Concentration/Initial Key-Reactant Concentration)*((Temperature*Initial Total Pressure)/(Initial Temperature*Total Pressure))))

Initial Key Reactant Concentration with Varying Density,Temperature and Total Pressure

Go Initial Key-Reactant Concentration = Key-Reactant Concentration*((1+Fractional Volume Change*Key-Reactant Conversion)/(1-Key-Reactant Conversion))*((Temperature*Initial Total Pressure)/(Initial Temperature*Total Pressure))

Key Reactant Concentration with Varying Density,Temperature and Total Pressure

Go Key-Reactant Concentration = Initial Key-Reactant Concentration*((1-Key-Reactant Conversion)/(1+Fractional Volume Change*Key-Reactant Conversion))*((Initial Temperature*Total Pressure)/(Temperature*Initial Total Pressure))

Activation Energy using Rate Constant at Two Different Temperatures

Activation Energy using Reaction Rate at Two Different Temperatures

Go Activation Energy = [R]*ln(Reaction Rate 2/Reaction Rate 1)*Reaction 1 Temperature*Reaction 2 Temperature/(Reaction 2 Temperature-Reaction 1 Temperature)

Temperature in Arrhenius Equation for First Order Reaction

Go Temperature in Arrhenius Eq for 1st Order Reaction = modulus(Activation Energy/[R]*(ln(Frequency Factor from Arrhenius Eqn for 1st Order/Rate Constant for First Order Reaction)))

Temperature in Arrhenius Equation for Zero Order Reaction

Go Temperature in Arrhenius Eq Zero Order Reaction = modulus(Activation Energy/[R]*(ln(Frequency Factor from Arrhenius Eqn for Zero Order/Rate Constant for Zero Order Reaction)))

Temperature in Arrhenius Equation for Second Order Reaction

Go Temperature in Arrhenius Eq for 2nd Order Reaction = Activation Energy/[R]*(ln(Frequency Factor from Arrhenius Eqn for 2nd Order/Rate Constant for Second Order Reaction))

Reactant Concentration using Reactant Conversion with Varying Density

Go Reactant Concentration with Varying Density = ((1-Reactant Conversion with Varying Density)*(Initial Reactant Concentration))/(1+Fractional Volume Change*Reactant Conversion with Varying Density)

Rate Constant for Second Order Reaction from Arrhenius Equation

Go Rate Constant for Second Order Reaction = Frequency Factor from Arrhenius Eqn for 2nd Order*exp(-Activation Energy/([R]*Temperature for Second Order Reaction))

Arrhenius Constant for Second Order Reaction

Go Frequency Factor from Arrhenius Eqn for 2nd Order = Rate Constant for Second Order Reaction/exp(-Activation Energy/([R]*Temperature for Second Order Reaction))

Rate Constant for First Order Reaction from Arrhenius Equation

Go Rate Constant for First Order Reaction = Frequency Factor from Arrhenius Eqn for 1st Order*exp(-Activation Energy/([R]*Temperature for First Order Reaction))

Arrhenius Constant for First Order Reaction

Go Frequency Factor from Arrhenius Eqn for 1st Order = Rate Constant for First Order Reaction/exp(-Activation Energy/([R]*Temperature for First Order Reaction))

Initial Reactant Conversion using Reactant Concentration with Varying Density

Go Reactant Conversion = (Initial Reactant Concentration-Reactant Concentration)/(Initial Reactant Concentration+Fractional Volume Change*Reactant Concentration)

Rate Constant for Zero Order Reaction from Arrhenius Equation

Go Rate Constant for Zero Order Reaction = Frequency Factor from Arrhenius Eqn for Zero Order*exp(-Activation Energy/([R]*Temperature for Zero Order Reaction))

Arrhenius Constant for Zero Order Reaction

Go Frequency Factor from Arrhenius Eqn for Zero Order = Rate Constant for Zero Order Reaction/exp(-Activation Energy/([R]*Temperature for Zero Order Reaction))

Initial Reactant Concentration using Reactant Conversion with Varying Density

Go Initial Reactant Conc with Varying Density = ((Reactant Concentration)*(1+Fractional Volume Change*Reactant Conversion))/(1-Reactant Conversion)

Initial Reactant Concentration using Reactant Conversion

Go Initial Reactant Concentration = Reactant Concentration/(1-Reactant Conversion)

Reactant Concentration using Reactant Conversion

Go Reactant Concentration = Initial Reactant Concentration*(1-Reactant Conversion)

Reactant Conversion using Reactant Concentration

Go Reactant Conversion = 1-(Reactant Concentration/Initial Reactant Concentration)

Temperature in Arrhenius Equation for Second Order Reaction Formula

What is significance of Arrhenius equation?

The Arrhenius equation explains the effect of temperature on the rate constant. There is certainly the minimum amount of energy known as threshold energy which the reactant molecule must possess before it can react to produce products. Most of the molecules of the reactants, however, have much less kinetic energy than the threshold energy at room temperature, and hence, they do not react. As the temperature is increased, the energy of the reactant molecules increases and become equal to or greater than the threshold energy, which causes the occurrence of reaction.

How to Calculate Temperature in Arrhenius Equation for Second Order Reaction?

Temperature in Arrhenius Equation for Second Order Reaction calculator uses Temperature in Arrhenius Eq for 2nd Order Reaction = Activation Energy/[R]*(ln(Frequency Factor from Arrhenius Eqn for 2nd Order/Rate Constant for Second Order Reaction)) to calculate the Temperature in Arrhenius Eq for 2nd Order Reaction, The Temperature in Arrhenius equation for second order reaction formula is defined as activation energy per universal gas constant times the difference of natural logarithm of frequency factor and rate constant. Temperature in Arrhenius Eq for 2nd Order Reaction is denoted by Temp_SecondOrder symbol.

How to calculate Temperature in Arrhenius Equation for Second Order Reaction using this online calculator? To use this online calculator for Temperature in Arrhenius Equation for Second Order Reaction, enter Activation Energy (E_a1), Frequency Factor from Arrhenius Eqn for 2nd Order (A_{factor-secondorder}) & Rate Constant for Second Order Reaction (K_second) and hit the calculate button. Here is how the Temperature in Arrhenius Equation for Second Order Reaction calculation can be explained with given input values -> 6.629941 = 197.3778/[R]*(ln(0.000674313/0.00051)).

FAQ

What is Temperature in Arrhenius Equation for Second Order Reaction?

The Temperature in Arrhenius equation for second order reaction formula is defined as activation energy per universal gas constant times the difference of natural logarithm of frequency factor and rate constant and is represented as Temp_SecondOrder = E_a1/[R]*(ln(A_{factor-secondorder}/K_second)) or Temperature in Arrhenius Eq for 2nd Order Reaction = Activation Energy/[R]*(ln(Frequency Factor from Arrhenius Eqn for 2nd Order/Rate Constant for Second Order Reaction)). Activation Energy is the minimum amount of energy that is required to activate atoms or molecules to a condition in which they can undergo chemical transformation, Frequency Factor from Arrhenius Eqn for 2nd Order is also known as the pre-exponential factor and it describes the frequency of reaction and correct molecular orientation & The Rate Constant for Second Order Reaction is defined as the average rate of the reaction per concentration of the reactant having power raised to 2.

How to calculate Temperature in Arrhenius Equation for Second Order Reaction?

The Temperature in Arrhenius equation for second order reaction formula is defined as activation energy per universal gas constant times the difference of natural logarithm of frequency factor and rate constant is calculated using Temperature in Arrhenius Eq for 2nd Order Reaction = Activation Energy/[R]*(ln(Frequency Factor from Arrhenius Eqn for 2nd Order/Rate Constant for Second Order Reaction)). To calculate Temperature in Arrhenius Equation for Second Order Reaction, you need Activation Energy (E_a1), Frequency Factor from Arrhenius Eqn for 2nd Order (A_{factor-secondorder}) & Rate Constant for Second Order Reaction (K_second). With our tool, you need to enter the respective value for Activation Energy, Frequency Factor from Arrhenius Eqn for 2nd Order & Rate Constant for Second Order Reaction 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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