The first-order rate constant for the decomposition of {\rmN_2O_5},
2{\rm N_2O_5}(g) \rightarrow 4{\rm NO_2}(g) + {\rm O_2}(g),
at 70^\circ {\rm C} is 6.82 \times 10^{ - 3}\;{\rm{s}}^{ - 1}.Suppose we start with 2.50×10-2 {\rm mol} of {\rm N_2O_5}(g) in avolume of 2.0 {\rm L}.

How many moles of {\rm N_2O_5} will remain after 4.8 {\rmmin}?
Express your answer using two significant figures.

The first order rate constant for the decomposition of N, 0, (g) at 70 degree C is 6.82 times 10^-3 s^-1. A container has a volume of 2.50 L. A quantity of 0.300 moles of N_2O_5 (g) are placed in the container, how many moles of N_2O_5, will remain after 6.0 minutes, what is the half-life of the N_2O_5at 70 degree C?

The decomposition of N_2O_5 has been studied in a solution of CCl_4 at 45 degree C. The reaction, 2N_2O_5 rightarrow 4NO_2 + O_2, is first order and k = 6.32 times 10^-4 s^-1. (a) What is the half-life of this reaction? (b) How long does it take to get to 12.5% of the original amount of N_2O_5? (c) How much N_2O_5 remains after 1 hour if the initial concentration was 0.50 mol/L? The CIO will dimer to Cl_2O_2, 2 ClO rightarrow Cl_2O_2 (a) Use the following data to determine the order of the reaction. (b) Write the rate law for the reaction. (c) Determine the rate constant for the reaction. (d) Determine the [ClO]_o at t = 0 min. (e) Determine the half-life of the reaction starting at t = 0 min. (f) Determine the half-life starting at the end of the first half-life.