A reaction `X_2(g)rarr Z(g) +1/2Y(g)` exhibits an increase in pressure from 150 mm to 170 mm in 10 minutes. The rate of disappearance of `X_2` in mm per minute is

A gaseous reaction : 2A(g) + B(g) to 2C(g) , Show a derease in pressure from 120 mm to 100 mm in 10 minutes. The rate of appearance of C is

A gaseous reaction 2A(g) to B(g)+5C(g) shows increase in pressure from 80 mm of Hg to 100 mm of Hg in 5 minutes. The rate of disappearance of A is:

A gaseous reaction A_(2)(g) rarr B(g) + (1)/(2) C(g) shows increase in pressure form 100 mm to 120 mm in 5 min . What is the rate of disappearance of A_(2) ?

A gaseous reaction A_(2)(g) rarr B(g) + (1)/(2) C(g) shows increase in pressure form 100 mm to 120 mm in 5 min . What is the rate of disappearance of A_(2) ?

For the first order reaction A(g) rarr 2B(g) + C(g) , the initial pressure is P_(A) = 90 m Hg , the pressure after 10 minutes is found to be 180 mm Hg . The rate constant of the reaction is

For the reaction H_(2) (g)+I_(2)(g) rarr 2HI(g) , the rate of disappearance of H_(2) is 1.0 xx 10^(-4) mol L^(-1) s^(-1) . The rate of appearance of HI will be

For the reaction at 273 K NO(g) + O_(3)(g) rarr NO_(2)(g) + O_(2)(g) It is observed that the pressure of NO(g) falls form 700 mm Hg to 500 mm Hg in 250 s . Calculate the average rate of reaction in (a) atm s^(-1) , (b) mol L^(-1) s^(-1) .

For the gaseous reaction A(g) rarr 4 B(g) + 3C( g) is found to be first order with respect to A. If at the starting the total pressure was 100mm Hg and after 20 minutes it is found to be 40 mm Hg. The rate constant of the reaction is :

Calculate the half life of the first-order reaction: C_(2)H_(4)O(g) rarr CH_(4)(g)+CO(g) The initial pressure of C_(2)H_(4)O(g) is 80 mm and the total pressure at the end of 20 min is 120 mm .

Calculate the half life of the first-order reaction: C_(2)H_(4)O(g) rarr CH_(4)(g)+CO(g) The initial pressure of C_(2)H_(4)O(g) is 80 mm and the total pressure at the end of 20 min is 120 mm .