`{:(I.,E_(a)=15m "kJ mol"^(-1),,DeltaH=-70 "kJ mol"^(-1)),(II.,E_(a)=30"kJ mol"^(-1),,DeltaH=-15 "kJ mol"^(-1)),(II.,E_(a)=60 "kJ mol"^(-1),,DeltaH=+250"kJ mol"^(-1)):}`
If above reactions are at same frequency factor then fastest and slowest reaction are:

Following are the values of E_(a) and DeltaH for three reactions carried out at the same temperature : I :E_(a)=20kJ mol^(-1),DeltaH=-60kJmol^(-1) II :E_(a)=10kJ mol^(-1),DeltaH=-20kJ mol^(-1) III : E_(a)=40 kJ mol^(-1),DeltaH=+15kJ mol^(-1) If all the three reaction have same frequency factor then fastest and slowest reaction are :

Following are the values of E_(a) and Delta H for three reactions carried out at the same temperature : I: E_(a) =20 kJ mol^(-1), Delta H =-60 kJ mol^(-1) II: E_(a) =10 kJ mol^(-1), Delta H =-20 kJ mol^(-1) III: E_(a) =40 kJ mol^(-1), Delta H=+15 kJ mol^(-1) If all the three reaction have same frequency factor then fastest and slowest reactions are :

ArarrB, DeltaH= -10 KJ mol^(-1), E_(a(f))=50 KJ mol^(-1) , then E_(a) of BrarrA will be

For a reaction A rarr B, E_(a) = 10 kJ mol^(-1), DeltaH = 5 kJ mol^(-1) . Thus, potential energy profile for this reaction is:

At 1 atm pressure, DeltaS=75JK^(-1)mol^(-1),DeltaH=30kJ" "mol^(-1) , the temperature of the reaction at equilibrium is

Given C_(2)H_(2)(g)+H_(2)(g)rarrC_(2)H_(4)(g): DeltaH^(@)=-175 " kJ mol"^(-1) DeltaH_(f(C_(2)H_(4),g))^(@)=50 " kJ mol"^(-1), DeltaH_(f(H_(2)O,l))^(@)=-280 " kJ mol"^(-1), DeltaH_(f(CO_(2)g))^(@)=-390 " kJ mol"^(-1) If DeltaH^(@) is enthalpy of combustion (in kJ "mol"^(-1) ) of C_(2)H_(2) (g), then calculate the value of |(DeltaH^(@))/(257)|

For a reaction DeltaH=+29kJ" "mol^(-1),DeltaS=-35KJ^(-1)" "mol^(-1) at what temperature, the reaction will be spontaneous?