Heat of hydrogenation of ethene is `x_(1)` and that of benzene is `x_(2)`. Hence, resonance energy is:

Heat of hydronization of ethene is x_(1) and that of benzene is x_(2) . Hence, resonance energy is :

Heat of hydrogenation of ethene is x_(1) and that of benzene is x_(2) . Hence resonance energy of benezene is

Heat of hydrogenation of ethene is x_(1) and that of benzene is x_(2) . Hence resonance energy of benezene is

Enthalpy of hydrogenation of benzene is DeltaH_(1) and for cyclohexene is DeltaH_(2) . The resonance energy of benzene is

Enthalpy of hydrogenation of benzene is DeltaH_(1) and for cyclohexene is DeltaH_(2) . The resonance energy of benzene is

Enthalpy of hydrogenation of cyclohexene is -119Kj/mol and that of benzene is -208kJ/mol. Based on these information, resonance energy of benzene can be calculated to be

Compounds having heat of hydrogenation lesser than that of cyclohexa-1, 4-diene i.e. [Hint resonance energy of benzene is 36 Kcal]

The resonance energy of benzene is

Find the heat of hydrogenation of cyclohexene if the heat of hydrogenation of benzene is 51 kcal mol^(-1) and its resonance energy is 36 kcal mol^(-1)

Heat of hydrogenation of cyclohexene to cyclohexane is -28.6kcal // mole. The observed heat of hydrogenation of benezene to cyclohexane is -49.8 kcal // mole. The resonance energy of benzene is :