For the following decomposition reaction, `N_2O_5 to 2NO_2+1/2 O_2` the rate is given by `(-d N_2O_5)/(dt)=k_1[N_2O_5],(d[NO_2])/(dt)=k_2[N_2O_5], (d[O_2])/(dt)=l_3[N_2O_5]`. The relation between `k_1,k_2` and `k_3` will be

2N_2O_5 rarr 4 NO_2 +O_2 If -(D[N_2O_5])/(dt) =k_1[N_2O_5] (d[NO_2])/(dt) =k_2[N_2O_5] ([O_2])/(dt) =k_3[N_2O_5] What is the relation between k_1, k_2 and k_3 ? .

The rate of the reaction 2N_(2)O_(5) to 4NO_(2) + O_(2) can be written in three ways: (-d[N_(2)O_(5)])/(dt)=k[N_(2)O_(5)] (d[NO_(2)])/(dt)=k'[N_(2)O_(5)] (d[O_(2)])/(dt)=k''[N_(2)O_(5)] The relationship between k and k′ and between k and k′′ are-

For the reaction , 2NH_3(g) rarrN_2(g)+3H_2(g) -(d[NH_3])/(dt)=k_1[NH_3] (d[N_2])/(dt)=k_2[NH_3] (d[H_2])/(dt)=k_3[NH_3] The relation between , k_1 , k_2 and k_3 may be given as

Consider the decomposition of N_2O_5 as N_2O_5rarr2NO_2+1/2O_2 The rate of reaction is given by (-d[N_2O_5])/(dt)=1/2(d[NO_2])/(dt)=2(d[O_2])/(dt)=k_1[N_2O_5]" Therefore,"(-d[N_2O_5])/(dt)=k_1[N_2O_5] , (+d[NO_2])/(dt)=2k_1[N_2O_5]=k_1^(')[N_2O_5],(d[O_2])/(dt)=1/2k_1[N_2O_5]=k_1^('')[N_2O_5] Choose the correct option.

For the reaction 2AtoB+3C , if -(d[A])/(dt)=k_(1)[A]^(2),-(d[B])/(dt)=k_(2)[A]^(2),-(d[C])/(dt)=k_(3)[A]^(2) the correct reaction between k_(1),k_(2) and k_(3) is :

Solid N_2O_5 is

The rate law for the reaction 2N_2 O_5 to 4NO_2 + O_2 is

For the reaction 2N_(2)O_(4)iff 4NO_(2) , given that (-d[N_(2)O_(4)])/(dt)=K " and "(d[NO_(2)])/(dt)=K , then

For the reaction, 2NO(g) + 2H_(2)(g) rarr N_(2)(g) + 2H_(2)O(g) The rate expression can be written in the following ways: (d[N_(2)])/(d t) = k_(1)[NO][H_(2)], (d[H_(2)O])/(d t) = k_(2)[NO][H_(2)] - (d[NO])/(d t) = k_(3)[NO][H_(2)], -(d[H_(2)])/(d t) = k_(4)[NO] [H_(2)] The relationship between k_(1), k_(2), k_(3), k_(4) is

For the reaction 2N_(2)O_(5 )rarrNO_(2)+O_(2) rate of reaction is :