For the reaction `A(g)rarrB (g) +C(g)` , the rate constant is given as `(P_(t)` is initial pressure and `P_(t)` is pressure at time t )-

For a first order gas phase reaction : " "A(g)rarr2B(g)+C(g) P_(0) be initial pressure of A and P_(t) the total pressure at time 't' . Integrated rate equation is -

For the reaction AB(g)iffA(g)+B(g) , AB is 33% dissociated at a total pressure of P, then

A gas can be liquefied at temperature T and pressure P if-

The value of K_p for the reaction 2H_2O(g) +2Cl_2(g) iff 4HCl(g) +O_2(g), is 0.035 atm at 400^@C , when the partial pressure are expressed in atmosphere. Calculate the value of K_c for the same reaction.

At a particular temperature, the value of K_(p) is 100 for the reaction, 2NO(g)hArrN_(2)(g)+O_(2)(g) occurring in a closed container. If the iniital pressure of NO(g) be 25 atm then calculate the partial pressures of NO, N_(2) and O_(2) at equilibrium.

Consider a first order gas phase decomposition reaction given below : A(g)rarrB(g)+C(g) The initial pressure of the system before decomposition of A was P_(i) After lapse of time 't' , total pressure of the system increased by x units and becomes 'P_(t)' . The rate constant k for the reaction is given as -

2A(g)rarr2B(g)+3C(g) is a first order reaction . When the reaction started , the pressure of the system was P_(0) , and it was found to be P_(t) after time t . The rate constant of the reaction can be expressed by the equation -

The total pressure at equilibrium of the reaction, XY(g)hArrX(g)+Y(g) is P . If the equilibrium constant for the reaction is K_p and K_p=P/8 , then the percent dissociation of XY is

Consider the following reaction for 2NO_(2)(g)+F_(2)(g)rarr2NO_(2)F(g) The expression for the rate of reaction in terms of the rate of change of partial pressure of partial pressure of reactant and product is/ are —