A plot of 1/T vs Ink for a reaction gives the slope `-1xx10^4K`. The energy of activation for the-reaction is (Given,R = `8.314 JK^-1 mol^-1`)

The specific reaction-rate constant for a decomposition reaction at 15^@C be 4.8 xx 10^35^-1 . If the energy of activation for the reaction be 80KJ mol^-1 then find the temperature in which it will be 1.5 xx 10^45^-1

The rate constant of a reaction at 200k is 0.1 times its value at TK . If the energy of activation of the reaction is 7.65"kJ.mol"^(-1) , find the value of 'T'?

The equilibrium constant K, at 27^@C for a homogeneous reaction is 10^-8 . The standard free energy change DeltaG^@ for the reaction (using R = 2 cal K^-1 mol^-1 )

The rate of a reaction doubles when its temperature changes from 300 K to 310 K. Activation energy of such a reaction will be ( R = 8.314 JK^-1 mol^-1 and log2 = 0.301)

The time required of 10% completion of a first order reaction at 298K is equal to that required for its 25% completion at 308K. If the pre-exponential factor for the reaction is 3.56xx10^9 S^(-1) . Calculate. Its rate constant at 318K and also the energy of activiation. [R=8.314 JK^(-1) mol^(-1) .

At 300K , frequency factor (A) of a first order reaction is 1000 times its rate constant . The activation energy of the reaction ("in kJ. Mol"^(-1)) is -

The rate constant of a reaction is 1.8xx10^3 min^(-1) . What is the order of the reaction?

For a given reaction t_(1/2)= 1/Ka The order of the reaction is

The rate of a reaction doubles when its temperature changes from 300K to 310K . Activation energy of such a reaction will be - (R=8.314"J.K"^(-1)"mol"^(-1) and log2=0.310)

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.