The decomposition of `A` into product has value of `k` as `4.5xx10^(3)s^(-1)` at `10^(@)C` and energy of activation of `60kJmol^(-1)`. At what temperature would `k` be `1.5xx10^(4)s^(-1)?`

(a) The decomposition of A into products has a value of K as 4.5 xx 10^(3)s^(-1) " at "10^(@)C and energy of activation 60kJ "mol"^(-1) . At what temperature would K be 1.5 xx 10^(4) s^(-1) ? (b) (i) If half life period of a first order reaction is x and 3//4^(th) life period of the same reaction is y, how are x and y related to each other ? (ii) In some cases it is found that a large number of colliding molecules have energy more than threshold energy, yet the reaction is slow. Why?

The first order gaseous decomposition of N_(2)O_(4) in to NO_(2) has a rate constant value k=4.5xx10^(3)s^(-1) at 1^(@)C and energy of acitivation 58kJmol^(-1) . What should be the rise in temperature in ("^(@)C) to get the value of K=1.00xx10^(4)s^(-1) . (log2.2=0.3424)

The rate constant for the decomposition of hydrocarbons is 2.418xx10^(-5)s^(-1) at 546K . If the energy of activation is 179.9kJ mol^(-1) , what will be the value of pre - exponential factor?

The rate constant of a reaction is 1.2 xx10^(-3) s^(-1) at 30^@C and 2.1xx10^(-3)s^(-1) at 40^@C . Calculate the energy of activation of the reaction.

The rate constant for a reaction is 1.5 xx 10^(-7) at 50^(@) C and 4.5 xx 10^(7)s^(-1) at 100^(@) C . What is the value of activation energy?

The decomposition of hydrocarbon follows the equation k=(4.5xx10^(11)s^(-1))e^(-28000K//T) Calculate E_(a) .

The decomposition of hydrocarbon follows the equation k=(4.5xx10^(11)s^(-1))e^(-28000K//T) Calculate E_(a) .

The rate constant of a reactant is 1.5 xx 10^(-3) at 25^(@)C and 2.1 xx 10^(-2) at 60^(@)C . The activation energy is

The decomposition of a hydrocarbon follows the equationk = (4.5 xx 10 ^(11) s^(-1) )e^(-28000) K/T. Calculate E_a .