Now we know that the rate law is of the formratek[A]x[C]Dependence on[A]: We use experiments 1 and 2 to evaluate x,because [A] is changed,
[B] does not matter, and [C] is unaltered. The observed rate change is due onlyto the
changed [A].[A] has been multipliedby a factor of 2.0[A] ratioThe rate changes by a factor of4.0rate ratioThe exponent xcan be deduced fromrate ratio([A] ratio)x
4.0(2.0)x so x 2 The reaction is second order in [A].From these results we can write the complete rate-law expression.ratek[A]^2 [B]^0 [C]^1 or ratek[A]^2 [C]We can evaluate the specific rate constant, k,by substituting any of the four sets of data into
the rate-law expression we have just derived. Data from experiment 2 giverate 2 k[A] 22 [C] 2k3.0 10 ^4 M^2 min^1The rate-law expression can also be written with the value of kincorporated.rate3.0 10 ^4 M^2 min^1 [A]^2 [C]This expression allows us to calculate the rate at which this reaction occurs with any known
concentrations of A and C (provided some B is present). As we shall see presently, changes in
temperature change reaction rates. This value of kis valid onlyat the temperature at which the
data were collected.You should now work Exercises 17 and 18.9.6 10 ^6 Mmin^1
(0.40 M)^2 (0.20 M)rate 2
[A] 22 [C] 29.6 10 ^6
2.4 10 ^60.40
0.20662 CHAPTER 16: Chemical Kinetics
Problem-Solving Tip:Check the Rate Law You Have DerivedIf the rate law that you deduce from initial rate data is correct, it will not matter which
set of data you use to calculate k.As a check, you can calculate kseveral times, once
from each set of experimental concentration and rate data. If the reaction orders in your
derived rate law are correct, then all sets of experimental data will give the same value
of k(within rounding error); but if the orders are wrong, then the kvalues will vary
considerably.