The decomposition of azo methane, at certain temperature acccording to the equation `(CH_(3))_(2)N_(2)toC_(2)H_(6)+N_(2)` is a first order reaction.
After 40 minutes from the start, the total pressure developed is found to be 350 mm Hg in place of initial pressure 200 mm Hg of azo methane. The value of rate constant k is :

A_(2)B is an ideal gas , which decompase according f to the equation : A_(2) B to A_(2) + (1)/(2)B_(2) . At start , the initial pressure is 100 mm Hg and after 5 minutes , the pressure is 120 mm Hg. What is the average rate of decomposition of A_(2)B ? Assume T and V are constant .

H_2O_2 decomposes with first order kinetics in a 3 lit. container. If the pressure developed in 10 min. is 380 mm, the average rate at 27^@C is

A gaseous mixture contains 56g of N_(2) , 44g of CO_(2) and 16g of CH_(4) . The total pressure of the mixture is 720 mm Hg. The partial pressure of CH_(4) is

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 rate expression for the decomposition of dimethyl ether in terms of partial pressures is given as Rate =k (pCH_(3) O CH_(3)) ^(3//2) . If the pressure is measured in bar and time in minutes, then what are the units of rate and rate constant ?

For the reaction, N_(2(g)) + 3H_(2(g)) rarr 2NH_(3(g)) . Heat of reaction at constant volume exceeds the heat of reaction at constant pressure by the value of xRT. The value of x is______

A_((g))toB_((g)) is a first order reaction. The initial concentration of A is 0.2 mol. "lit"^(-1) . After 10 minutes the concentration of B is found to be 0.18"mol. lit"^(-1) . The rate constant ("in min"^(-1)) for the reaction is

Assume that the decomposition of HNO_(3) can be represented by the following equation 4HNO_(3(g)) hArr 4NO_(2(g)) + 2H_(2) O_((g)) + O_(2(g)) and the reaction approaches equilibrium at 400K temperature and the copper turnning 0 atm pressure. At cquilibrium partial pressure of HNO_(3) is 2 atm. Calculate Kc in ("mole" //L)^(3) at 400 K.