The decomposition of `N_2O_5` occurs as, `2N_2O_5 to 4NO_2 + O_2` and follows first order kinetics, hence:

The decomposition of N_(2)O_(5) occurs as, 2N_(2)O_(5) rarr4NO_(2)+O_(2) and follows I order kinetics, hence:

If the decomposition of nitrogen oxide as 2N_2O_5 to 4NO_2 + O_2 follows a first order kinetics . Calculate the rate constant for a 0.05M solution if the instantaneous rate is 1.5 xx10^(−6) mol/l/s ?

If the decomposition of nitrogen oxide as 2N_2O_5 to 4NO_2 + O_2 follows a first order kinetics. K=3.0 × 10^(-5) sec^(-1) . What concentration of N_2O_5 would give a rate of 2.45 xx 10^(−5) "mol L"^(-1) s^(-1) ?

The thermal decomposition of N_(2)O_(5) occues as: 2N_(2)O_(5) rarr 4NO_(2)+O_(2) Experimental studies suggest that rate of decomposition of N_(2)O_(5) rate of formation of NO_(2) or rate of formation of O_(2) all becomes double if concentration of N_(2)O_(5) is doubled. If rate of formation of O_(2) is 16 g//hr then rate of decomposition of N_(2)O_(5) and rate of formation of NO_(2) respectively is

A : The decomposition of gaseous N_2O_5 follows first order kinetics. R : The plot of log of its partial pressure versus time is linear with slope , -k/(2.303) and having intercept equal to log P.

The reaction 2N_(2)O_(5) hArr 2NO_(2)+O_(2) follows first order kinetics. Hence, the molecularity of the reaction is