NVAEasyJEE 2023Arrhenius Equation & Activation Energy

JEE Chemistry 2023 Question with Solution

AB\textbf{A} \rightarrow \textbf{B}

The rate constants of the above reaction at 200K200 \, \text{K} and 300K300 \, \text{K} are 0.03min10.03 \, \text{min}^{-1} and 0.05min10.05 \, \text{min}^{-1} respectively.

The activation energy for the reaction is _____ J\text{J} (Nearest integer)

Given: ln10=2.3\ln 10 = 2.3, R=8.3J K1mol1R = 8.3 \, \text{J K}^{-1} \text{mol}^{-1}, log5=0.70\log 5 = 0.70, log3=0.48\log 3 = 0.48, log2=0.30\log 2 = 0.30

Answer

Correct answer:2520

Step-by-step solution

Standard Method

Given: Rate constants are K200=0.03min1K_{200} = 0.03 \, \text{min}^{-1} at 200K200 \, \text{K} and K300=0.05min1K_{300} = 0.05 \, \text{min}^{-1} at 300K300 \, \text{K}.

Find: Activation energy EaE_a.

Use the Arrhenius relation:

log(K300K200)=Ea2.3×8.314(1T11T2)\log \left( \frac{K_{300}}{K_{200}} \right) = \frac{E_a}{2.3 \times 8.314} \left( \frac{1}{T_1} - \frac{1}{T_2} \right)

Substituting the given values:

log(0.050.03)=Ea2.3×8.314(12001300)\log \left( \frac{0.05}{0.03} \right) = \frac{E_a}{2.3 \times 8.314} \left( \frac{1}{200} - \frac{1}{300} \right)

Now,

log(0.050.03)=log5log3=0.700.48=0.22\log \left( \frac{0.05}{0.03} \right) = \log 5 - \log 3 = 0.70 - 0.48 = 0.22

So,

0.22=Ea2.3×8.314×(12001300)0.22 = \frac{E_a}{2.3 \times 8.314} \times \left( \frac{1}{200} - \frac{1}{300} \right)

And,

12001300=160000\frac{1}{200} - \frac{1}{300} = \frac{1}{60000}

Hence,

0.22=Ea2.3×8.314×1600000.22 = \frac{E_a}{2.3 \times 8.314} \times \frac{1}{60000}

Solving for EaE_a:

Ea=2519.88JE_a = 2519.88 \, \text{J}

Therefore, the activation energy is 2520J2520 \, \text{J} to the nearest integer.

Using Log Difference Quickly

Given: The required relation is between the ratio of rate constants and activation energy.

Find: Activation energy EaE_a.

A quick route is to first evaluate the logarithmic term directly:

log(0.050.03)=log5log3=0.22\log \left( \frac{0.05}{0.03} \right) = \log 5 - \log 3 = 0.22

Then use the temperature difference factor:

12001300=160000\frac{1}{200} - \frac{1}{300} = \frac{1}{60000}

Substitute these two simplified values into the Arrhenius form and solve for EaE_a.

This works because the equation depends only on the ratio of the two rate constants, not on their individual absolute values separately.

Therefore, the activation energy comes out to 2520J2520 \, \text{J} approximately.

Common mistakes

  • Using ln\ln form and log\log values together without the 2.32.3 conversion is incorrect because the constants must match the logarithm base. If the equation is written in common logarithm form, keep the 2.3R2.3R factor.

  • Calculating 12001300\frac{1}{200} - \frac{1}{300} incorrectly is a common error. It is not 1100\frac{1}{100}; the correct value is 160000\frac{1}{60000}. Always take the LCM carefully before substitution.

  • Taking log(0.050.03)\log \left( \frac{0.05}{0.03} \right) as 0.050.03\frac{0.05}{0.03} is wrong because the logarithm must be evaluated first. Use log5log3\log 5 - \log 3 from the given values.

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