For `A_((s))+B_((s))toC_((s))`,rate=`k[A]^(1//2)[B]^(2)`, if initial concentration of A and B are increased by factors 4 and 2 respectively, then the initial rate is changed by the factor:

The rate expression for reaction A(g) +B(g) rarr C(g) is rate =k[A]^(1//2)[B]^(2) . What change in rate if initial concentration of A and B increases by factor 4 and 2 respectively ?

In the reaction A+B hArr AB , if the concentration of A and B is increased by a factor of 2 , it will cause the equilibrium concentration of AB to change to

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:

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:

The rate expression for the reaction A(g) + B(g) to C(g) is rate = KC_A^2 C_B^½ . What changes in the initial concentration of A and B will cause the rate of reaction increase by a factor of eight?

For a hypothetical reaction, A+B to C+D , the rate =k[A]^(-1//2)[B]^(3//2) . On doubling the concentration of A and B the rate will be

For the reaction A + B products, it is observed that: (1) on doubling the initial concentration of A only, the rate of reaction is also doubled and (2) on doubling te initial concentration of both A and B , there is a charge by a factor of 8 in the rate of the reaction. The rate of this reaction is given by

For a reaction 2A + Bto Products, doubling the initial concentration of both the reactants increases the rate by a factor of 8, and doubling the concentration of B alone doubles the rate. The rate law for the reaction is:

In the reaction 2A+B to A_2B , Rate = k[A]^2 [ B ] if the concentration of A is doubled and that of B is halved, then the rate of reaction will: