For an endothermic reaction, `Delta H` represents the enthalpy of the reaction in kJ `mol^(-1)`. The mininum amount of activation energy will be

For an endothermic reaction, where Delta H represents the enthalpy of reaction in kJ mol^(-1) , the minimum value for the energy of activation will be

An endothermic reaction is represented by the graph :

For an exothermic reaction ArarrB , the activation energy is 65kJmol^(-1) and enthalpy of reaction is 42kJmol^(-1) . The activation energy for the reaction BrarrA will be:

Dimerisation of NO_2, is an exothermic reaction. If enthalpy of reaction is /_\H, then the minimum value of activation energy for forward reaction (E_a) will be

For an endothermic reaction energy of activation is E_(a) and enthlpy of reaction is Delta H (both in kJ "mol"^(-1) ). Minimum value of E_(a) will be

The activation energy of exothermic reaction ArarrB is 80 kJ "mol"^(-1) . The heat of reaction is 200 kJ "mol"^(-1) . The activation energy for the reaction Brarra ( in kJ/mol) will be :

In an exothermic reaction X rarr Y , the activation energy is 100 kJ mol^(-1) of X . The enthalphy of the reaction is -140 kJ mol^(-1) . The activation energy of the reverse reaction Y rarr X is

Enthalpy of a reaction at 27^(@)C is "15 kJ mol"^(-1) . The reaction will be feasible if entropy is

An exothermic reaction XrarrY has an activation energy of 90kJ mol^(-1) of X and the heat of reaction is 250 kJ . Find the activation energy of the reaction YrarrX .

An endothermic reaction with high activation energy for the forward reaction is given by the diagram