Difficult
The time required for $10 \%$ completion of a first order reaction at $298 \,K$ is equal to that required for its $25 \%$ completion at $308 \,K$. If the value of $A$ is $4 \times 10^{10} \,s^{-1}$,calculate $k$ at $318 \,K$ and $E_a$.
(N/A) For a first order reaction,$t = \frac{2.303}{k} \log \frac{a}{a-x}$.
At $298 \,K$,$t = \frac{2.303}{k} \log \frac{100}{90} = \frac{0.1054}{k}$.
At $308 \,K$,$t' = \frac{2.303}{k'} \log \frac{100}{75} = \frac{0.2877}{k'}$.
Given $t = t'$,so $\frac{0.1054}{k} = \frac{0.2877}{k'}$,which gives $\frac{k'}{k} = 2.7296$.
Using the Arrhenius equation: $\log \frac{k'}{k} = \frac{E_a}{2.303 \,R} \left( \frac{T' - T}{T \,T'} \right)$.
$\log (2.7296) = \frac{E_a}{2.303 \times 8.314} \left( \frac{308 - 298}{298 \times 308} \right)$.
$E_a = \frac{2.303 \times 8.314 \times 298 \times 308 \times \log (2.7296)}{10} = 76640.1 \,J \,mol^{-1} = 76.64 \,kJ \,mol^{-1}$.
To calculate $k$ at $318 \,K$ using $\log k = \log A - \frac{E_a}{2.303 \,R \,T}$:
$\log k = \log (4 \times 10^{10}) - \frac{76640.1}{2.303 \times 8.314 \times 318} = 10.6021 - 12.5876 = -1.9855$.
$k = \text{antilog}(-1.9855) = 1.034 \times 10^{-2} \,s^{-1}$.
At $298 \,K$,$t = \frac{2.303}{k} \log \frac{100}{90} = \frac{0.1054}{k}$.
At $308 \,K$,$t' = \frac{2.303}{k'} \log \frac{100}{75} = \frac{0.2877}{k'}$.
Given $t = t'$,so $\frac{0.1054}{k} = \frac{0.2877}{k'}$,which gives $\frac{k'}{k} = 2.7296$.
Using the Arrhenius equation: $\log \frac{k'}{k} = \frac{E_a}{2.303 \,R} \left( \frac{T' - T}{T \,T'} \right)$.
$\log (2.7296) = \frac{E_a}{2.303 \times 8.314} \left( \frac{308 - 298}{298 \times 308} \right)$.
$E_a = \frac{2.303 \times 8.314 \times 298 \times 308 \times \log (2.7296)}{10} = 76640.1 \,J \,mol^{-1} = 76.64 \,kJ \,mol^{-1}$.
To calculate $k$ at $318 \,K$ using $\log k = \log A - \frac{E_a}{2.303 \,R \,T}$:
$\log k = \log (4 \times 10^{10}) - \frac{76640.1}{2.303 \times 8.314 \times 318} = 10.6021 - 12.5876 = -1.9855$.
$k = \text{antilog}(-1.9855) = 1.034 \times 10^{-2} \,s^{-1}$.
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The activation energy of the backward reaction exceeds that of the forward reaction by $2RT$ (in $J \ mol^{-1}$). If the pre-exponential factor of the forward reaction is $4$ times that of the reverse reaction,the absolute value of $\Delta G^{\ominus}$ (in $J \ mol^{-1}$) for the reaction at $300 \ K$ is. . . . . (Given; $\ln(2)=0.7, RT=2500 \ J \ mol^{-1}$ at $300 \ K$ and $G$ is the Gibbs energy)
For the following reactions:
$A \xrightarrow{700 \ K}$ Product
$A \xrightarrow[\text{catalyst}]{500 \ K}$ Product
it was found that $E_{a}$ is decreased by $30 \ kJ/mol$ in the presence of a catalyst. If the rate remains unchanged,the activation energy for the catalysed reaction is (Assume pre-exponential factor is same):
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$A \xrightarrow[\text{catalyst}]{500 \ K}$ Product
it was found that $E_{a}$ is decreased by $30 \ kJ/mol$ in the presence of a catalyst. If the rate remains unchanged,the activation energy for the catalysed reaction is (Assume pre-exponential factor is same):
DifficultJEE MAIN 2020
View SolutionThe rate of the process doubles with every $10 \ K$ increase in temperature. When the temperature is increased from $303 \ K$ to $353 \ K$,how much will the rate of the process increase?
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