A reaction `A_(2)+B_(2)to2AB` occurs by the following mechanism:
`A_(2)hArr A+A`…………(fast)
`A+B_(2)toAB+B`……….(slow)
`A+BtoAB`…………..(fast) Its order would be:

Which are true for the reaction: A_(2) hArr 2C+ D

For a reaction the following mechanism has been proposed , 2A+BtoD+E A+BtoC+D (slow), A+CtoE (fast) The rate law a expression for the reaction is

Mechanism of a hypothetical recation X_(2)+Y_(2) to 2XY is given below (i) X_(2) to X+X("fast") (ii) X+Y_(2) hArr XY+Y("Slow") (iii) X+Y to XY("fast") The overall order of the reaction will be

Elementary unimolecular reaction have first order rate laws, elementary bimolecular reaction have second order rate laws. A rate law is often derived from a proposed mechanism by imposiing the steady state approximation by assuming that there in pre equilibrium A proposal mechanism must be constant with the experimental rate law. The decomposition of O_(3) obeys the mechanism given below, Step 1: O_(3)hArrO_(2)+(O)- fast Step 2: O_(3)+(O)toO_(2)+O_(2)- slow H_(2)+Br_(2)to2HBr Mechaism : Br_(2)hArr2Br (fast) H_(2)+brtoHBr+H (slow) H+BrtoHBR (Fast) Order of the reaction is

At constant temperature 80% AB dissociates into A_(2) and B_(2) then the equilibrium constant for 2AB_((g)) harr A_(2(g)) +B_(2(g))

For the reaction AB_(2(g)) hArr AB_((g)) + B_((g)) if alpha is negligiable w.rt 1 then degree of dissociation (alpha) of AB_(2) is proportional to

Depletion of ozone occurs as : 2O_3 to 3O_2 Step 1: O_3 overset(K_c)(iff) O_2 (O) (fast) Step 2: O_3 + (O) overset(K_c)(iff) 2O_2 (slow) What is the order of the reaction

A and B are two elements . The compound formed with A and B is A_(2) ,B . What are the valencies of A and B .