When `N_(2)` goes to `N_(2)^(+)`, then N-N bond distance ……….and when `O_(2)` goes to `O_(2)^(+)` the O-O bod distance…….

In N_(2)O, the N - N distance corresponds to

The bonds present in N_(2)O_(5) are

The two bonds N=O and N--O in H_(3) CNO_(2) are of same bond length due to

The bonds present in N_2O_5 are

The changes in bond length with respect to N - N and O - O , when N_(2) becomes N_(2)^(+) and O_(2) becomes O_(2)^(+) are respectively

The bond dissociation energy ( E) and bond length ( R) of O_(2),N_(2) and F_(2) follow the order as :

The following data were obtained during the first order thermal decomposition of N_(2)O_(5) (g) at constant volume : 2N_(2) O_(5)(g)to 2N_(2)O_(4)(g) +O_(2)(g) Calculate the rate constnat.

The correct order of N-O bond length in No, NO_(2)^(-) and NO_(3)^(-) will be

The initial concentration of N_(2)O_(5) in the following first order reaction . N_(2)O_(5) to 2NO_(2)(g) + 1//2O_(2)(g) was 1.24 xx 10^(-2) mol L^(-1)