In a gaseous reaction `A+2B iff 2C+D` the initial concentration of B was 1.5 times that of A. At equilibrium the concentration of A and D were equal. Calculate the equilibrium constant `K_(C)`.

A + B hArrC + D . If finally the concentrations of A an d B are both equal but at equilibrium concentration of D will be twice of that of A then what will be the equilibrium constant of reaction.

In a first-order reaction A rarr B, if k is rate constant and initial concentration of the reactant A is 0.5 M, then the half-life is :

Rate law for the reaction A + 2B to C is found to be rate = k [A][B] concentration of reactant B is doubled, keeping the concentration of A constant the value of rate will be

For the reaction A + 2B rarr C , the reaction rate is doubled if the concentration of A is doubled. The rate is increased by four times when concentrations of both A and B are increased by four times. The order of the reaction is

Calculate the equilibrium concentration ratio of C to A if equimolar ratio of A and B were allowed to come to equilibrium at 300K. A(g)+B(g) iff C(g) +D(g) , DeltaG^(@)= -830 cal.

5 litre vessel contains 2 moles of each of gases A and B at equilibrium. If 1 mole each of A and B are removed. Calculate K_(C) for the reaction A(g) iffB(g)

Consider the reaction, 2A + B rarr Products When concentration of B alone was doubled, the half-life did not change. When the concentration of A alone was doubled, the rate increased by two times. The units of rate constant for this reaction are -

The rate constant of the reaction A rarr B is 0.6 xx10^-3 mole per second. If the concentration of A is 5 M, then concentration of B after 20 minutes is:

In the system A_((s))hArr2B_((g))+3C_((g)) , if the concentration of C at equilibrium is increased by a factor of 2 , it will cause the equilibrium concentration of B to change to:

Consider a reaction A(g)overset(k=0.1 M min^(-1))to2B(g) . If initial concentration of A is 0.5 M then select correct graph. a) b) c) d)