Chemistry, Third edition

264 14 · SPEED OF CHEMICAL REACTIONS

In an experiment carried out at 65 °C, the concentration of

N 2 O 5 changed with time as follows:

[N 2 O 5 ]/mol dm^3 Time after start of reaction/h

.10 10 ^2 0 (i.e. at start)
8.6 10 ^2 0.50

7.3 10 ^2 1.0
6.3 10 ^2 1.5

5.4 10 ^2 2.0
4.6 10 ^2 2.5

3.9 10 ^2 3.0
3.4 10 ^2 3.5
2.9 10 ^2 4.0

(i) What is the overall order of reaction?

(ii)Plot [N 2 O 5 (g)] against time. Join the points with a smooth

curve.

(iii)From your graph, find the initial rate of reaction.

(iv)Calculate the rate constant for the reaction at 65 °C and

state its units.

(v)What is the half-life of N 2 O 5 at this temperature?

14.6.The hydrolysis of bromomethane,

CH 3 Br(l)OH(aq)CH 3 OH(aq)H 2 O(l)

follows the rate expression:

rate of reaction k[CH 3 Br(l)][OH(aq)]

The rate constant kwas found to be 3.0  10 ^4 mol^1 dm^3 s^1

at 300 K.

(i)With excess OH(aq), the reaction was found to be pseudo

first order. What does this mean? What would be the re-

action order if the bromomethane (and not the OH(aq))

was in excess?

(ii)In an experiment [OH(aq)] 0 1.0 10 ^2 mol dm^3 and

[CH 3 Br(l)] 0 1.0 10 ^4 mol dm^3. What is the value of

(a) the initial rate of reaction, (b) the pseudo-first-order

rate constant and (c) the pseudo-reaction half-life, at 300 K

at this hydroxide concentration?

14.7.The reaction of chlorine oxide (ClO•) radicals with

nitrogen dioxide,

ClO•(g)NO 2 (g)N 2 (g)ClONO 2 (g)N 2 (g)

is an important ‘sink’ for chlorine oxide radicals in the atmo-

sphere. (The nitrogen absorbs the excess energy of colliding

molecules and acts as a type of catalyst.) The reaction was stud-

ied in the laboratory and showed the following dependence

upon the concentrations of the reactants at 298 K:

(i) Write down the rate expression for the reaction.

(ii)Calculate an average value of k(298 K).

(iii)Is the rate expression consistent with the formation of

chlorine nitrate being a single-stage reaction? Explain.

14.8.Draw an energy profile, similar to Fig. 14.7, for an

endothermicreaction.

14.9.Show, starting from the equation [A]t[A] 0 ekt, that

the time (symbolized t0.99) it takes for a first-order reaction to

use up 99% of the reactant is given by the expression

t0.994.605

k

(HintAftert0.99seconds, the ratio of initial to actual concentra-

tions is 1/100.)

14.10.The reaction:

2CO(g)O 2 (g)2CO 2 (g)

is catalysed by powdered platinum in ‘catalytic converters’.

Draw sketches (similar to those found in Fig. 14.12) which show

a possible mechanism for the reaction. For simplicity, represent

carbon monoxide as CO.

Initial concentration/mol dm^3

Experiment [ClO(g)] 0 [NO 2 (g)] 0 [N 2 (g)] 0 Initial rate of

reaction/

mol dm^3 s^1

11 .0  10 ^5 2.0 10 ^5 3.0 10 ^5 3.5 10 ^4

20 .5  10 ^5 2.0 10 ^5 3.0 10 ^5 1.8 10 ^4

31 .0  10 ^5 4.0 10 ^5 3.0 10 ^5 7.1 10 ^4

40 .5  10 ^5 2.0 10 ^5 6.0 10 ^5 3.6 10 ^4

The graphical determination of the Arrhenius activation energy is discussed in Appendix 14 on the

website.