`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 .

AB_(2) dissociates as AB_(2)(g) hArr AB(g)+B(g) . If the initial pressure is 500 mm of Hg and the total pressure at equilibrium is 700 mm of Hg. Calculate K_(p) for the reaction.

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 a first order gas phase reaction : A_((g)) to 2B_((g)) +C_((g)) P_(0) be initial pressure of A and P_(t) the total pressure at time 't'. Integrated rate equation 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) ?

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:

2 is the equilibrium constant for the reaction A_(2)+B_(2)hArr 2AB at a given temperature. What is the degree of dissociation for A_(2)" or "B_(2)

The displacement y(t) of a particle depends on time according in equation y(t)=a_(1)t-a_(2)t^(2) . What is the dimensions of a_(1) and a_(2) ?

The reaction , 2AB(g) + 2C(g) to A_(2(g)) + 2BC_((g)) proceeds according to the mechanism . I. 2AB hArr A_(2)B_(2) (fast) II. A_(2)B_(2)+C to A_(2)B + BC (slow ) III. A_(2)B+C to A_(2)+BC (fast) what will be the initial rate taking [AB] = 0.2 M and [C] = 0.5 M ? The K_(c) for the step I is 10^(2) M^(-1) and rate constant for the step II is 3.0 xx 10^(-3) mol^(-1) min^(-1)

A_(2)B_((g)) is introduced in a vessel at 1000K . If partial pressure of A_(2)B(g) "is" 1 atm initially and K_(P) for reaction A_(2)B_((g))hArr2A(g)+B(g) "is" 81xx10^(-6) then calculate percentage of dissociation of A_(2)B .