The overall rate `(d[P])/(dt)`, for the reaction `2A overset(K)hArr B,B+Coverset(k_f)rarrP` is given by

Mechanism of the reaction is: A overset(k_(1))rarrB, 2Aoverset(k_(2))rarr C + D What is (-d[A])/(dt) ?

Mechanism of the reaction is: A_(2) overset(k_(2))hArr 2A A + B overset(k_(2))rarr C A_(2) + C overset(k)rarr D + A What is (d[D])/(dt) ?

Conisder the following reactions: I. A+B underset(k_(-1))overset(k_(1))hArr C II. C + B overset(k_(2))rarr D Then k_(1)[A][B]-k_(-1)[C]-k_(2)[C][B] is equal to (a) (-d[A])/(dt) (b) (-d[B])/(dt) (c) (d[C])/(dt) (d) (d[D])/(dt)

Mechanism of the reaction is: A_(2) underset(k')overset(k)hArr 2A A + B_(2) overset(k_(2))rarr C + B B + A_(2) overset(k_(2))rarr C + A What is (-d[A_(2)])/(dt)

The following mechanism has been proposed for the exothermic catalyzed cmplex reaction: A + B overset("Fast")rarr IABoverset(k_(1))rarrAB+Ioverset(k_(2))rarrP+A If k_(1) is much smaller than k_(2) , the most suitable qualitative plot of potential energy (PE) versus reaction coordinates for the above reaction is

Mechanism of the reaction is: A underset(k_(1))overset(k_(2))hArr B ...(i) B+A overset(k_(3))hArr C ...(ii) ul(bar(2A rarr C)) ...(iii) What is (a) (-d[A])/(dt) , (b ) (d[C])/(dt)

Conisder the following proposed mechanism A underset(k_(2))overset(k_(1))hArr B , B+C overset(k_(3))rarrD For the overall reaction A+CrarrD , assuming B to be an intermediate described by the steady state approximation, write the rate expresison for [A] .

The relation between K_(P) and K_(C) for the reaction A(g)+B(g) hArr C(g)+2D(g) is -

The rate law expresison is given for a typical reaction, n_(1)A + n_(2) B rarrP as r = k[A]^(n)[B]^(n2) . The reaction completes only in one step and A and B are present in the solution. If the reaction occurs in more than one step, then the rate law is expressed by consdering the slowest step, i.e., for S_(N)l reaction r = k[RX] . If the eraction occurs in more than one step and the rates of the steps involved are comparable, then steady state approximation is conisdered, i.e., the rate of formation of intermediate is always equal to the rate of decompoistion of the intermediate. Conisder the reaction: [[I_(2) underset(k_(1))overset(k_(2))hArr2I("rapid equilibrium")],[H_(2)+2I overset(k_(3))rarr 2HI("slow")]] If we increase the concentration of I_(2) two times, then the rate of formation of HI will

The rate law expresison is given for a typical reaction, n_(1)A + n_(2) B rarrP as r = k[A]^(n)[B]^(n2) . The reaction completes only in one step and A and B are present in the solution. If the reaction occurs in more than one step, then the rate law is expressed by consdering the slowest step, i.e., for S_(N)l reaction r = k[RX] . If the eraction occurs in more than one step and the rates of the steps involved are comparable, then steady state approximation is conisdered, i.e., the rate of formation of intermediate is always equal to the rate of decompoistion of the intermediate. Conisder the reaction: [[I_(2) underset(k_(1))overset(k_(2))hArr2I("rapid equilibrium")],[H_(2)+2I overset(k_(3))rarr 2HI("slow")]] Which of the following expresison is correct?