I. `E_(a)=20kJ"mol"^(-1)" "DeltaH=-60kj"mol"^(-1)`
II. `E_(a)=30kj"mol"^(-1)" "DeltaH=-20kj"mol"^(-1)`
III. `E_(a)=60kj"mol"^(-1)" "DeltaH=+25kj"mol"^(-1)`
If all the three reaction have same frequency factor then fastest and slowest reaction are

The enthalpy changes for the following processes are listed below: Cl_(2(g)) rarr 2Cl_((g)) , DeltaH = 242.3 kJ mol^(-1) I_(2(g)) rarrr 2I_((g)) , DeltaH = 151.0 kJ mol^(-1) ICl_((g)) rarr I_((g)) + Cl_((g)) , DeltaH = 211.3 kJ mol^(-1) I_(2(s)) rarr I_(2(g)) , DeltaH = 62.76 kJ mol^(-1) Given that the standard states for iodine and chlorine are I_(2(s)) and Cl_(2(g)) , the standard enthalpy of formation for ICT is:

DeltaH_f^@ values (in kJ mol^(-1) ) for graphite , diamond and C_60 are respectively

O + 2e^(-) to O^(-) , DeltaH = 639 kJ/mole O + e^(-) to O^(-) DeltaH o= -141 kJ/mole O^(-) + e^(-) to O^(-) , DeltaH = x kJ/mole What is the value of x ?

A catalyst lowered the energy of activation by 25 kJ mol^(-1) .How many times , the rate reaction increases?

Delta H_(f)^(@) value (in KJ "mol"^(-1) ) for graphite, diamond and C_(60) are respectively

Which ions are present in MgO(s) Calculate the enthalpy change for the reaction Mg(s) + 1//2O_(2)(g) rarr MgO(s) What kind of enthalpy change is this? Standard enthalpy of formation of MgO. DeltaH_(atom(O))= +249 kJ mol^(-1) " " DeltaH_(atom(Mg))=+148 kJ mol^(-1) DeltaH_("1st ionisation energy" (Mg))=+738 KJ mol^(-1) " " DeltaH_(2nd "electron energy "(Mg))= +145 1 kJ mol^(-1) DeltaH _("1st electron affinity "(O))= -141 kJ mol^(-1) " " DeltaH_(2nd " electron affinity "(O)) =+798 kJ mol^(-1) DeltaH_("lattice energy "(MgO))= - 3791 kJ mol^(-1)

For the reaction at 298 K, 2A+BtoC DeltaH=400 kJ mol^(-1) and DeltaS=0.2 kJ K^(-1)mol^(-1). At what temperature will the reaction becomes spontaneous considering DeltaH and DeltaS to be constant over the temperature range?

The heat of combustion ( kJ "mol"^(-1) ) is highest for

At 300 K, the equilibrium constant for a reaction is 10. the standard free energy change (in kJ mol^(-1) ) for the reaction is

Construct a Born-Haber cycle and use it to calculate the first electron affinity of chlorine. DeltaH_(atom(CI))= +122 kJ mol^(-1) " " DeltaH_(atom(Mg))=+148 kJ mol^(-1) DeltaH_("1st ionisation energy" (Mg))=+738 KJ mol^(-1) " " DeltaH_(2nd " ionisation cnergy"(MgCI_(2))= +1451 kJ mol^(-1) DeltaH _("lattice energy "(MgCI_(2))= -2526 kJ mol^(-1) " " DeltaH_(2nd " formation "(MgCI_(2)) =-641 kJ mol^(-1)