[" For an isomerisation reaction "A rightleftarrows B" ,the ternperature "],[" dependence of equilibrium constant is given by "],[qquad log_(a)K=4.0-(2000)/(T)]

For an isomerisation reaction, A hArr B , the temperature dependence of equilibrium constant is given by Log_0K=4.0 -(2000)/T Find the value of DeltaS^0 at 300 k in cal.

For an isomerisation reaction, A hArr B , the temperature dependence of equilibrium constant is given by Log_0K=4.0 -(2000)/T Find the value of DeltaS^0 at 300 k in cal.

For a first order reaction ArarrP , the temperature (T) dependent rate constant (K) was found to follow the equation log k=-(2000)(1)/(T)+6.0 . The pre- exponential factor A and the activation energy E_(a) , respectively, are :

For a first order reaction A rarr P , the temperature (T) dependent rate constant (k) was found to follow the equation log k = -2000(1//T) + 6.0 . The pre-exponential factor A and the activation energy E_(a) , respective, are

For a first order reaction A rarr P , the temperature (T) dependent rate constant (k) was found to follow the equation log k = -2000(1//T) + 6.0 . The pre-exponential factor A and the activation energy E_(a) , respective, are

For a first order reaction A rarr P, the temperature (T) dependent rate constant (k) was found to follow the equation log k=(2000)/T +6.0 The pre-exponential factor A and the activation energy E_a , respectively, are

For a first order reaction A rarr P , the temperature (T) dependent rate constant (k) was found to follow the equation log k = -2000(1//T) + 6.0 . The pre-exponential factor A and the activation energy E_(a) , respective, are