The initial rate, -(d[A])/dt at t = 0 was found to be `2.6 xx 10^2 mol L^-1s^-1` for the reaction `A+ 2B to` Products The initial rate, (d[B])/dt, at `t approx 0` is

In the reaction 3A to 2B , rate of reaction +('d(B)')/(dt) is equal to

The rate of a reaction is 1.2xx10^-3 L mol^-1s^-1 , What is the order of the reaction?

dx/dt + x cos t = 1/2 sin 2 t

The initial concentration of the reactant in a zero order reaction is 1.386 "mol.L"^(-1) The half-life of the reaction is 20s. Calculate: the rate constant

The initial rate of a first order reaction is 5.2 xx 10^(-6)" mol.lit"^(-1).s^(-1) at 298 K. When the initial concentration of reactant is 2.6xx10^(-3)" mol.lit"^(-1) , calculate the first order rate constant of the reaction at the same temperature.

The rate constant of the reaction ArarrB " is " 0.6xx10^(-3)"mol.L"^(-1).s^(-1) . If the concentration of A is 5(M) , then concentration of B after 20 min is -

For the reaction A+BrarrC , the initial rate was x"mol.L"^(-1).s^(-1) . After times t_(1) andt_(2) , the rates were found to be y and z "mol.L"^(-1).s^(-1) respectively . Arrange x , y and z in order of their increasing values.

solve the differential equation (1+t^2)dx/dt=2t

ArarrB at a specific temperature, the rate constant of the reaction is 2.8xx10^(-3)"mol"^(-1).L.s^(-1) If the concentration of A is halved, what will be the rate of the reaction?

At a given temperature , the rate constant for the reaction ArarrB " is" 2.8xx10^(-3)"L.mol"^(-1).s^(-1) . If the concentration of A is halved, what would the rate of be the reaction be ?