`k_(1)=xhr^(-1), k_(1): k_(2) =1:10`. Calculate `([C])/([A])` after one hour from the start of the reaction. Assuming only A was present in the beginning.

When K_(c)gt1 for a chemical reaction,

If K_(p) for a reaction is 0.1 at 27^(@)C the K_(c ) of the reaction will be

An organic compound (A) decomposes according to two parallel first order mechanism. (k_(1))/(k_(2))=1.303 and k_(2) =2hr^(-1) Calculate the ratio of concentration of C to A, if an experiment is allowed to start with only A for one hour?

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)) ]]

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)