In an exo-ergic reaction the binding energies of reactants and products are `E_(1), E_(2)` respectively then

In an endo-ergic reaction the binding energies of reactants and products are E_(1), E_(2) respectively

The binding energies of the atom of elements P and Q are E_(P) and E_(Q) respectively. There atoms of element Q fuse on atom of element P . The correct relation between E_(P), E_(Q) and e will be

The binding energies of the nuclei A and B are E_(alpha)and E_(alpha) respectively. Three atoms of the element B fuse to give one atom of element A and an energy Q is released. Then, E_(a),E_(b) Q are relaetd as

The energy required to form the intermediate, called activated complex (C ) is known as activation energy (E_(a)) . The diagram is obtained by plotting potential energy vs. reaction coordinate. Reaction coordinate represents the profile of energy change when reactants change into products. Some energy is released when the complex decomposes to form products. So, the heat of the reaction depends upon the nature of reactants and products. If a reaction A+Brarr C , is exothermic to the extent of 30 kJ mol^(-1) and the forward reaction has an activation energy of 249 kJ mol^(-1) , the activation energy for reverse reaction in kJ mol^(-1) is:

In the accompanied diagram E_(R), E_(P) and E_(X) represents the energy of the reactants products and activated complex respectively Which of the following is the activation energy for the backward reaction?

If m_(1) and m_(2) are masses of two reactants in any reaction, having their gram equivalent masses E_(1) and E_(2) respectively, which of the following equatios represents the law of equivence correctly?