Kinetics II PDF Past Paper

Summary

This document contains a series of chemistry kinetics questions. It includes problems related to reaction rates, rate expressions, and reaction mechanisms, along with questions on the activation energy and order of a reaction, providing examples and calculations. It also discusses the steady-state approximation, applying kinetics principles to reaction schemes and unimolecular reactions. This document is likely a part of a chemistry course or examination.

Full Transcript

Kinetics II

Question 1

a) Define the following terms which relate to the reaction N2 + 3H2 2NH3
i) the rate of reaction
ii) the rate expression or rate law
iii) the rate constant

b) A gas phase reaction of the type 2A B is monitored at 298 K by measuring the total pressure
(Pt = PA + PB).

t/s 0 100 200 300 400
Pt / Torr 400 322 288 268 256

Note that at t = 0, the pressure is due to A only.

i) Derive an expression which gives the pressure of A, PA, in terms of the total pressure Pt.

ii) Show that the data are consistent with a second order reaction.

iii) Show that the rate constant at 298 K is k2 = 8.06 x 106 Torr1 s1

iv) If the rate constant at 37°C is k2 = 1.73 x 105 Torr1 s1, show how to calculate the
activation energy of the reaction.

Question 2

The kinetics of the thermal decomposition of ozone can be accounted for by the following mechanism:

(1) O3 O2 + O k1
(2) O + O3 O2 + O 2 k2
(3) O + O2 + M O3 + M k3

a) Show that the steady state concentration of oxygen atoms is given by

k1[O3]
[O] = k [O ] + k [O ][M]
2 3 3 2

b) Why is the species M included in both sides of reaction (3)?

c) Show that the rate of disappearance of ozone according to the above mechanism is

d[O3] 2k1k2[O3]2
 dt = k [O ] + k [O ][M]
2 3 3 2

d) Outline the assumptions upon which the use of the steady-state approximation is based. Are these
assumptions justified?
Question 3

a) Explain, with examples, the meaning of the term rate law in chemical kinetics. Include in your
answer an explanation of why the concept of overall order is not applicable to all, but only to some
rate laws.

b) Reductions by H2 in aqueous solution can be catalysed by Cu2+ ions; the rates are independent of
the concentration of the substrate being reduced. A mechanism proposed for these reactions is:
k1
Cu2+ + H2 CuH+ + H+
k1
k2
+
CuH + Cu 2+ 2Cu+ + H+

fast

2Cu+ + Ox 2Cu2+ + Red

where Ox and Red represent oxidised and reduced forms of the substrate. By treating CuH+ as a
reactive intermediate, show that the theoretical rate law for the consumption of H2, is

k1k2[Cu2+]2[H2]
rate =
k1[H+] + k2[Cu2+]

Show that the rates given below for reaction at 100°C with a fixed Cu2+ concentration of
0.1 mol dm3 are consistent with the mechanism, and determine the constant k1 and the ratio
k1/k2. The Henry’s law constant (solution concentration / gas pressure) for H2 solution under the
conditions of the experiment is 7.14 x 104 mol dm3 bar1.

p(H2) / bar 5 10 20 20 20 20 20
[H+] /mol dm3 0.01 0.01 0.01 0.1 0.2 0.4 0.5
rate / mol dm3 s1 3.5 7.0 14.0 11.48 9.57 7.18 6.38

Question 4

a) Derive an equation for the rate of conversion of A into B according to the following reaction
scheme.

k1
A + A A* + A

k1
A* + A A + A

k2
A* B

b) Explain why so-called unimolecular reactions that follow this scheme display a change in kinetics
from first order to second order overall as the pressure is lowered and why the addition of inert gas
can significantly influence the reaction rate.
c) The cis-trans isomerisation of an alkene was studied as a function of pressure at constant
temperature, and the following effective first-order rate constants were measured.

concentration x 106 /mol dm3 4.0 7.0 14.0 65.0
rate constant x 105 / s1 1.28 1.47 1.69 1.89

i) Show that the reaction kinetics, over the given concentration range, are consistent with the
reaction scheme in a).

ii) Calculate k1 and the limiting value of the effective first order rate constant at high
pressures.

iii) Explain why the reaction kinetics associated with many unimolecular reactions deviate
significantly from the quantitative predictions of the reaction scheme in a).

Question 5

a) Explain what is meant by the half life of a chemical reaction. The reaction

OH + C2H6 H2O + C2H5

was studied at 300 K. For initial concentrations [OH]0 = [C2H6]0 = a0, show that the half life of OH
radicals is given by (a0k1)1, where k1 is the bimolecular rate constant for the reaction.

b) For initial concentrations [OH]0 = [C2H6]0 = 1.5 x 1010 mol dm3, the half life at 300 K was found to
be 44 s. Determine the OH radical half life when [OH]0 = 1.5 x 1010 mol dm-3 and C2H6]0 = 1.5 x 107
mol dm3 (i.e. in great excess over [OH]0).

c) For [OH]0 = [C2H6]0 = 1.5 x 1010 mol dm3, the half life t1/2 of OH varies with temperature as shown
in the table below. Deduce what you can from these data.

T / K 300 450 900
t1/2 / s 44 12 1.85

d) For the recombination reaction represented by the stoichiometric equation O + O + M O2 + M,
the half life of oxygen atoms increases with increasing temperature. Account for this behaviour.