For a reaction, if effective rate constant k' is given b
`k=(2k_2)/k_3(k_1/k_5)^(1//5)`
where `k_1,k_2,k_3,k_5` are rate constants for different steps of the reaction
The effective activation energy is

For a reaction, if effective rate constant k' is given b k=(2k_2)/k_3(k_1/k_5)^(1//5) where k_1,k_2,k_3,k_5 are rate constants for different steps of the reaction The effective frequency factor

For a reaction, if effective rate constant k' is given b k=(2k_2)/k_3(k_1/k_5)^(1//5) where k_1,k_2,k_3,k_5 are rate constants for different steps of the reaction Which one is correct ?

A reaction is represented by A to^(k_1) B (slow). A+B to^(k_2) C (fast). Where k_1 and k_2 are the rate constants of the mechanistic steps. The rate of production of C will be given by

A reaction takes place in various steps. The rate constant for first, second, third and fifth steps are k1, k2, k3 and k5 respectively. The overall rate constant is is given by: k = k_(2)/k_(1) (k_(1)/k_(2))^(1/2) activation energy are 40,60, 50 and 10 kJ/mol respectively, find the overall energy of activation (kJ/mol).

A reaction is represented by : A to B slow and A+B to C (fast) where k_1 and k_2 are the rate constants of the mechanistic steps. The rate of production of B will be given by :

60.A consecutive reaction occurs with two equilibria which co-exist together P(k_(1))/(k_(2) Q (k_(3))/(k_(4) R Where k_(1) , k_(2) , k_(3) and k_(4) are rate constants.Then the equilibrium constant for the reaction P harr R is (1) (k_(1)*k_(2)) / (k_(3)*k_(4) ) (2) (k_(1)*k_(4)) / (k_(2)k_(3) ) (3) k_(1) * k_(2) * k_(3)*k_(4) (4) (k_(1)*k_(3)) / (k_(2)k_(4)) ]]

For the reaction (i) Aoverset(k_(I))toP (ii) Boverset(K_(II))toQ , following observation is made. Calculate (k_(1))/(k_(II)) , where k_(I) and k_(II) and rate constant for the respective reaction.

K_(1) and K_(2) are the rate constants of forward and backward reactions. The equilibrium constant K of the reaction is -