[" 1.Consider the following reaction,"],[2N_(2)O_(5)longrightarrow4NO_(2)+O_(2);(d[NO_(2)])/(dt)=k_(2)[N_(2)O_(5)]],[(d[O_(2)])/(dt)=k_(3)[N_(2)O_(5)]" and "(d)/(dt)[N_(2)O_(5)]=k_(1)]

Consider the following reaction, 2N_(2)O_(5)rarr4NO_(2)+O_(2),(d[NO_(2)] )/(dt)=k_(2)[N_(2)O_(5)] , (d[O_(2)])/(dt)=k_(3)[N_(2)O_(5)]" and "(d)/(dt)[N_(2)O_(5)]=k_(1) The relation between k_(1), k_(2) and k_(3) is

For the reaction, N_(2)O_(5) rarr 2NO_(2)+1/2O_(2), Given -(d[N_(2)O_(5)])/(dt)=K_(1)[NO_(2)O_(5)] (d[NO_(2)])/(dt)=K_(2)[N_(2)O_(5)] and (d[O_(2)])/(dt)=K_(3)[N_(2)O_(5)] The relation in between K_(1), K_(2) and K_(3) is:

For the reaction N_(2)O_(5)to2NO_(2)+1/2O_(2) , Given (-d[N_(2)O_(5)])/(dt)=K_(1)[N_(2)O_(5)], (d[NO_(2)])/(dt)=K_(2)[N_(2)O_(5)] and (d[O_(2)])/(dt)=K_(3)[N_(2)O_(4)] . The relation in between K_(1),K_(2) and K_(3) is

2N_(2)O_(5)rarr 4NO_(2)+O_(2),(d[N_(2)O_(5)])/(dt)=k_(1)[N_(2)O_(5)] . (d[NO_(2)])/(dt)=k_(2)[N_(2)O_(5)] and (d[O_(2)])/(dt)=k_(3)[N_(2)O_(5)] , the relation between k_(1), k_(2) and k_(3) is

2N_(2)O_(5)rarr 4NO_(2)+O_(2),(d[N_(2)O_(5)])/(dt)=k_(1)[N_(2)O_(5)] . (d[NO_(2)])/(dt)=k_(2)[N_(2)O_(5)] and (d[O_(2)])/(dt)=k_(3)[N_(2)O_(5)] , the relation between k_(1), k_(2) and k_(3) is

2N_(2)O_(5)rarr NO_(2)+O_(2), (d[N_(2)O_(5)])/(dt)=k_(1)[N_(2)O_(5)], (d[NO_(2)])/(dt)=k_(2)[N_(2)O_(5)] and (dO_(2))/(dt)=k_(3)[N_(2)O_(5)] , the relation between k_(1), k_(2) and k_(3) is

The rate of the reaction: 2N_(2)O_(5)rarr4NO_(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-

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-