CHAP. 9: CHEMICAL KINETICS [CONTENTS] 278
9.2.3.9 Type.
aA +bB→products. (9.43)9.2.3.10 Kinetic equation
−
dcA
dτ=kcAcB =⇒ adx
dτ=k(cA0−a x)(cB0−b x). (9.44)This equation can be rearranged to
dx
dτ=k′(c′A0−x)(c′B0−x). (9.45)wherek′=b k,c′A0=cA0/aandc′B0=cB0/b. Comparison of (9.45) with (9.37) shows that the
equations are formally identical. Hence in this case we can use equations (9.38) through (9.40)
in such a way that we substitutek′, c′A0, c′B0in place of k,cA0andcB0, respectively. Equation
(9.38), e.g., will thus rearrange to
k′τ=1
(c′A0−c′B0)lnc′B0c′A
c′A0c′B=
1
(c′A0−c′B0)lnc′B0(c′A0−x)
c′A0(c′B0−x). (9.46)
9.2.3.11 Pseudofirst-order reactions.
It often happens that one of the reactants, e.g. B, is in large excess at the beginning of the
reaction,cB0≈cA0. In the course of the reaction, its concentration changes very little and it
may be considered constant. The kinetic equation (9.37) then rearranges to
−
dcA
dτ=k′cA, where k′=kcB.The equation is formally identical with the first-order kinetic equation (9.23), and conse-
quently we speak about a pseudofirst-order reaction.
Note:In literature we sometimes encounter the less correct term “pseudo-unimolecular”
reaction.