The low bond energy of `F_(2)` is explained by :

If the bond dissociation energy of XY, x_ (2) AND y_(2) (all diatomic molecules) are in the ratio of 1 : 1 : 0.5 and Delta_(f)H for the formation of XY is - 200 kJ mol^(-1) . The bond dissociation energy of X_(2) will be :

Bond energy of a molecule

Bond entnalpy of F_(2) is less than of Cl_(2) .

H_(2)(g) + (1)/(2)O_(2)(g) rarr H_(2)O(g) Delta H = -242 kJ mol^(-1) . Bond energy of H_(2) and O_(2) are 436 mol^(-1) and 500 mol^(-1) respectively. What is the bond energy of the O-H bond ?

The dissociation energy of CH_(4) and C_(2)H_(6) are respectively 1508 and 2594 kJ mol^(-1) respectively. The bond energy of C-C bond is

From the following bond energies : {:(H-H "bond energy :" 431.37 kJ mol^(-1)),(C=C "bond energy :" 606.10 kJ mol^(-1)),(C-C "bond energy : "336.49 kJmol^(-1)),(C-H "bond energy :" 410.50kJ mol^(-1)):} calculate the bond energy of the following reaction : H-overset(overset(H)(|))( C)= overset(overset(H)(|))(C )-H + H - H rarr H - underset(underset(H)(|))overset(overset(H)(|))(C )- underset(underset(H)(|))overset(overset(H)(|))(C)- H

Wittig reaction : The reaction of a phosphorus ylide with an aldehyde (or) ketone introduces a carbon-carbon double bond is place of the carbonyl bond. Driving froce of the reaction is high bond energy of (P = O). (DeltaH=-ve) . , Major product (A) is :

Wittig reaction : The reaction of a phosphorus ylide with an aldehyde (or) ketone introduces a carbon-carbon double bond is place of the carbonyl bond. Driving froce of the reaction is high bond energy of (P = O). (DeltaH=-ve) . , Major product (A) is

Wittig reaction : The reaction of a phosphorus ylide with an aldehyde (or) ketone introduces a carbon-carbon double bond is place of the carbonyl bond. Driving froce of the reaction is high bond energy of (P = O). (DeltaH=-ve) . . Product (A) is :