`N_(2)O_(5)` decomposes according to equation,
`2N_(2)O_(5) rarr 4 NO_(2)+O_(2)`
(a) What does `-(d[N_(2)O_(5)])/(dt)` denote?
(b) What does `(d[O_(2)])/(dt)` denote?
(c) What is the unit of rate of this reaction?

The reaction 2N_(2)O_(5)hArr 2N_(2)O_(4)+O_(2) is

For the first order reaction 2N_(2)O_(5)(g) rarr 4NO_(2)(g) + O_(2)(g)

For a reaction, 2N_(2)O_(5)(g) to 4NO_(2)(g) + O_(2)(g) rate of reaction 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

Gaseous N_(2)O_(5) decomposes according to the following equation: N_(2)O_(5)(g) rarr 2NO_(2)(g) + (1)/(2)O_(2)(g) The experimental rate law is -Delta [N_(2)O_(5)]//Delta t = k[N_(2)O_(5)] . At a certain temerature the rate constant is k = 5.0 xx 10^(-4) sec^(-1) . In how seconds will the concentration of N_(2)O_(5) decrease to one-tenth of its initial value ?

For the reaction : 2N_(2)O_(5) rarr 4NO_(2) +O_(2) , the rate of reaction in terms of O_(2) is d[O_(2)] /dt. In terms of N_(2)O_(5) , it will be :

Consider the reaction 2N_(2) O_(5(g) ) to 4NO_(2(g)) +O_(2(g)) in liquid bromine If --(d[N_(2)O_(5) ])/(dt)=0.02 M s^(-1) then NO_(2) is formed at _______.

For a reaction , 2N_(2)O_(5)rarr4NO_(2)+O_(2), the rate is directly proportional to [N_(2)O_(5)]. At 45^(@)C, 90% of the N_(2)O_(5) react in 3600 s. The value of the rate constant is