The rate law expression of a reaction `2A+B rarr A_(2)B` is rate =`k[A]^(2)` with rate constant k =0.65 `mol^(-1) L s^(-1)`
calculate rate of reaction when
(a) `[A]=0.25 mol L^(-1) [B]=1.84 mol L^(-1)`

The rate law expression of a reaction 2A+B rarr A_(2)B is rate = k[A][B]^(2) with rate constant k =0.65 mol^(-1) L s^(-1) calculate rate of reaction when concentration of A has been reduced to 1//4 and concentration of B has been reduced by 1//4

A first order reaction with respect to reactant A has a rate constant 6.5 min^(-1) . If we start with 2.0 mol L^(-1) of A when would A reach the value 0.5 mol L^(-1)

For a reaction A + B rarr C + D , the rate equation is, Rate = K[A]^(3/2)[B]^(1/2) . Give the overall order and molecularity of reaction.

The rate constant for the reaction, 2N_(2)O_(5) rarr 4NO_(2) +O_(2) is 3.0 xx10^(-5) s^(-1) If the rate is 2.40 xx10^(-5) mo L^(-1) S^(-1) then the concentration of N_(2)O_(5) (in mo L^(-1) ) is

The rate expression for the reaction A (g) + B (g) rarr C (g) is rate = kC_(A)^(2)C_(B)^(1//2) . What changes in the initial concentrations of A and B will cause the rate of reaction to increase by a factor of eight?