The decomposition of a hydrocarbon follows the equation `k= (4.5 xx 10^11s^-1)e^-28000K/T.` Activation energy of the reaction is

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

The rate constant of a first order reaction follows the equation logk(s^(-1))=22.3-(12.16xx10^(3))/(T)K Find the activation energy of the reaction.

The rate constant of a chemical reaction at 600K is 1.6xx10^(-5)s^(-1) . The activation energy of the reaction is 209"kJ.mol"^(-1) . Calculate its rate constant at 700K.

The rate constant of decomposition of B is 4.8xx10^(3)s^(-1) " at "15^(@)C . If the activation energy of the reaction is 80 kJ.mol , at what temperature will the rate constant of the reaction be 1.5xx10^(4)s^(-1) ?

The rate constant for the first order decomposition of H_2O_2 is given by the following by the equation log k= 14.34 - 1.25 xx 10^4 K/T Calculate E-a for this reaction and at what temperature will its half-period be 256 minutes /.

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

The rate of a reaction at 400 K is 10 times than the rate of the reaction at 200 K . Calculate activation energy of the reaction.

The rate constant for the first order decomposition of H_(2)O_(2) is given by the following equation: logk=14.34-1.25xx10^(4)K//T Calculate E_(a) for this reaction and rate constant k if its half-life period is 256 minutes.

The decomposition of H_(2)O_(2) is a first order reaction . The rate constant of the reaction can be expressed as logk=14.34-(1.25xx10^(4))/(T) . Calculate the activation energy of the reaction . At what temperature does the half-life of the reaction become 265min?