The initial concentration of `N_(2)O_(5)` in the following first order reaction .
`N_(2)O_(5) to 2NO_(2)(g) + 1//2O_(2)(g) ` was `1.24 xx 10^(-2) mol L^(-1)`

The initial concentratin of N_(2)O_(5) in the following first order reaction N_(2)O_(5)(g) to 2NO_(2)(g)+(1)/(2O_(2))(g) was 1.24 xx10^(-2) mol L^(-1) at 318K. The concentration of N_(2)O_(5) after 60 minutes was 0.20xx10^(-2) mol L^(-1). Calculate the rate constant of the reaction at 138 K.

The initial concentration of N_(2)O_(5) in the first order reaction N_(2)O_(5)to2NO_(2)+1/2O_(2) was 1.24xx10^(-2) mole /lit at 318 k. The concentration of N_(2)O_(5) after 60 min is 0.20xx10^(-2) mole/lt. Calculate the rate constant of reaction at 318 K

For the first order reaction 2N_(2)O_(5(g))to4NO_(2(g))+O_(2(g))

The decomposition of N_(2)O_(5) in C Cl_(4) at 318K has been studies by monitoring the concentration of N_(2)O_(5) in the solution. Initially the concentration of N_(2)O_(5) is 2.33 mol L^(-1) and after 184 minutes, it is reduced to 2.08 mol L^(-1). The reaction takes placed according to the equation 2N_(2)O_(5)(g)to 4 NO _(2)(g) +O_(2)(g) Calculate the average rate of this reaction in terms of hours, minutres and seconds. What is the rate of proudction of NO_(2) during this period ?

Thermal decomposition for N_2O_5(g) follows 1st order kinetics as per N_2O_5(g) to 2NO_2(g) + 1/2O_2(g) . Initial pressure of N_2O_5 is 100mm. After 10 minutes, the pressure developed is 130mm, what is rate constant?

The decomposition of O_(3)(g) follows first order kinetics and is given by O_(3)(g) rarr O_(2)(g)+O(g) The rate constant for this reaction is 1.0xx10^(-3)s^(-1) . The initial pressure of O_(3)(g) is 100 atm. What will be the partial pressure ( in atm ) of O_(3), O_(2), O respectively after 38.38 minutes ?

N_(2(g))+O_(2(g))rarr 2NO_(2(g))-Q is ……………..