For `N_2 + O_2 to 2NO,` initially `N_2 & O_2` are at pressures 500mm & 700 mm at t = 0. If the pressure of `N_2` is 480 mm at t = 20 min average rate of reaction 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 .

For 2A(g) B(g) +3C(g) , Pressure of A at t = 0 is 500 mm, then total pressure of A, B & C at t = 10 min is( in mm)

For a gaseous phase reaction A_((g)) + 3 B_((g)) hArr 2 C_((g)) , initial pressure is 600 mm at 1 : 3 molar ratio of A and B . If the equilibrium pressure of A is 100 mm , that of B & C respectively are (in mm)

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?

N_(2)O is obtained by the reaction of

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

Thermal decomposition of HI(g) on Gold surface follows Zero order kinetics. With initial pressure 1000 mm. If the pressure after 20 sec is 960 mm w.r.t HI(g) rate constant is