The rate constant for a first order reaction at `300^(@)C` for which `E_(a)` is 35 kcal `mol^(-1)` and frequency constant is `1.45 xx 10^(11) s^(-1)` is

The unit of rate constant for a zero order reaction is s^(-1) .

The rate constant of a first order reaction is 1.54×10^(−3)sec^(−1) . Calculate its half life period.

The specific rate constant for a first order reaction is 60xx10^(-4) sec^(-1) . If the initial concentration of the reactant is 0.01mol L^(-1) , the rate is

The rate constant of first order reaction is 10^(-2)"min"^(-1) . The half-life period of reaction is

The rate constant for the reaction, 2N_(2)O_(5) rarr 4NO_(2) + O_(2) is 3.0 xx 10^(-5) s^(-1) . If the rate is 2.40 xx 10^(-5) mol L^(-1) s^(-1) , then the initial concentration of N_(2)O_(5) (in mol L^(-1) ) is

The energy of activation of a first order reaction is 187.06 kJ mol^(-1) at 750 K and the value of pre-exponential factor A is 1.97xx10^(12)s^(-1) . Calculate the rate constant and half life. (e^(-30)= 9.35xx10^(-14))

The value of rate constant for a second order reaction is 6.7 xx 10^(-5) mol^(-) L s^(-) at 298 K and 1.64 xx 10^(-4) mol^(-) L s^(-) at 313 K. Find the Arrhenius frequency factor A and activation energy of the reaction.

The rate constant of a first order reaction is 6.9xx10^(-3)s^(-1) . How much time will it take to reduce the initial concentration to its 1//8^("th") value?