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Vant Hoff's Equation and Effect of Temperature on Equilibrium Constant

The rate cons...

Question

The rate constant $(k)$ of a reaction is measured at different temperatures $(T)$ , and the data are plotted in the given figure. The activation energy of the reaction in $k J m o l^{- 1}$ is:
Here,
$R$ is gas constant :

0.5 R

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R

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1.5 R

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2 R

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Solution

The correct option is B $R$
For a reaction, relationship between temperature and rate constant follows the equation,
$k = A e^{- \frac{E_{a}}{R T}} . . . e q n (i)$
where,
$k$ : Rate constant
$E_{a}$ : Activation energy (in J/mol)
$R$ : Gas constant
$T$ : Temperature of reaction (in Kelvin(K))
$A$ : Arrhenius factor or frequency factor or pre-exponential factor. It is constant, specific to a particular reaction

Taking $l n_{e}$ both sides in eqn(i)
$l n k = l n A - \frac{E_{a}}{R T}$
Comparing with the given graph,
Slope is $= - \frac{E_{a}}{R}$
$\frac{(10 - 0)}{(0 - 10)} = - \frac{E_{a}}{R}$
$- 1 = \frac{- E_{a}}{R} E_{a} = R$

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