A graph between `log t_((1)/(2))` and log a (abscissa), a being the initial concentration of A in the reaction For reaction `Ato`Product, the rate law is :

Give relation between half reaction time (t_(1//2)) and initial concentration of reactant for (n-1) order reaction

The product of half life (t_(1//2)) and the square of initial concentration of the reactant is constant. Then the order of reaction is

For the reaction A+B products, it is observed that (a) On doubling the initial concentration of A only, the rate of reaction is also doubled (b) On doubling the initial concentration of both A and B, there is a change by a factor of 8 in the rate of the reaction. The rate of this reaction is given by

The rate expression for the reaction A_((g))+B_((g))toC_((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?

The rare law for a reaction between th substances A and B is given by Rate =k[A]^(m)[B]^(n) On doubling the concentration of A and halving the concentration of B, the ratio of the new rate to the earlier rate of the reaction will be as

Drawn the graph that the concentration 'R', of the reactant and 't' the reaction time for a zero Order reaction.

In a reactio between A and B, the initial rate of reaction (r_(0)) was measured for different initial concentrations of A and B as given below : What is the order of the reaction with respect to A and B?

For a reaction Ato Product, half life is 50 min, when the initial concentration of A is 4 molar Half life of same reaction is 80 min, when the initial concentration of A is 2 molar. Then