A chemical reaction was carried out at 300 K and 280 K. The rate constants were found to be `K_(1) and K_(2)` respectively. Then:

Two reactions R_(2) and R_(2) have identical pre - exponential factors. Activations enery of R_(1) exceeds that of R_(2) by 10 kJ mol_(-1) . If k_(1) and k_(2) are rate constants for rate constants for reactions R_(1) and R_(2) respectively at 300k , then In (k_(2)/k_(1)) is equal to (R=8.314 J mol^(-1)K^(-1))

Two reactions R_(1) and R_(2) have identical pre - exponential factors. Activations enery of R_(1) exceeds that of R_(2) by 10 kJ mol_(-1) . If k_(1) and k_(2) are rate constants for rate constants for reactions R_(1) and R_(2) respectively at 300k , then In (k_(2)/k_(1)) is equal to (R=8.314 J mol^(-1)K^(-1))

Acertain rection has equilibrium constant 10 and 100 at 300K and 400K respectively. The ratio of Delta G^(@) at 300K and 400K respectively

A reaction takes place in various steps. The rate constatn for first, second, third and fifth steps are k_(1),k_(2),k_(3) and k_(5) respectively The overall rate constant is given by k=(k_(2))/(k_(3))(k_(1)/(k_(5)))^(1//2) If activation energy are 40, 60, 50, and 10 kJ/mol respectively, the overall energy of activation (kJ/mol) is :

Two reaction : X rarr Products and Y rarr Products have rate constants k_(1) and k_(2) at temperature T and activation energies E_(1) and E_(2) , respectively. If k_(1) gt k_(2) and E_(1) lt E_(2) (assuming that the Arrhenius factor is same for both the Products), then (I) On increaisng the temperature, increase in k_(2) will be greater than increaisng in k_(1) . (II) On increaisng the temperature, increase in k_(1) will be greater than increase in k_(2) . (III) At higher temperature, k_(1) will be closer to k_(2) . (IV) At lower temperature, k_(1) lt k_(2)

The dissociation constant of two weak acids are k_(a_(1)) & k_(a_(2)) respectively. Their relative strength is -

In a reaction A+BhArrC+D the rate constant of forward reaction & backward reaction is K_(1) and K_(2) then the equilibrium constant (K) for reaction is expressed as:

Rate constant for a chemical reaction taking place at 500K is expressed as K=A. e^(-1000) The activation energy of the reaction is :

The activation energies of two reactions are E_(1) & E_(2) with E_(1)gtE_(2) . If temperature of reacting system is increased from T_(1) (rate constant are k_(1) and k_(2) ) to T_(2) (rate constant are k_(1)^(1) and k_(2)^(1) ) predict which of the following alternative is correct.

The rate constants of a reaction at 500 K and 700 K are 0.02 s^(-1) and 0.07 s^(-1) respectively. Calculate the values of E_a and A.