The reaction `2NO(g) + H_(2)(g) to N_(2)O(g) + H_(2)O(g)` follows the rate law `(dp(N_(2)O))/(dt)= k(p_(NO))^(2)p_(H_(2))`. If the reaction is initiated with `p_(NO)= 1000` mm Hg and `p_(H_(2))`=10mm Hg. The reaction may be considered to follow:

For a reaction 2NO(g)+H_(2)(g)rarrN_(2)O(g)+H_(2)O(g) the rate law is dp (N_(2)O)// dt=k(P_(NO))^(2)(P_(H_(2))) The half life of the reaction when (P_(NO))_(0)=10 mmHg and (P_(H_(2)))_(0) =1200 mmHg is found to be 830 s The half life when (P_(NO))_(0)=20 mmHg and (P_(H_(2)))_(0)=1200 mmHg will be

In the process 2N_(2)O_(5)(g) to 4NO_(2)(g) + O_(2)(g) at t = 10, rate of reaction w.r.t. N_(2)O_(5), NO_(2) & O_(2) respectively are:

For the reaction, 2NO_((g) + O_(2(g) rarr 2NO_(2(g) the rate law is given as. Rate =k [NO]^2[O_2] The order of the reaction with respect to O_2 is _______

For the reaction 3H_(2)(g)+N_(2)(g) rarr2NH_(3) (g") express the rate of reaction in terms of -d[H_(2)]//dt-d[N_(2)]//dt and d[NH_(3)]//dt