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New 21st Century Chemistry
Suggested answers to in-text activities and unit-end exercises
Topic 10 Unit 37
In-text activities
Checkpoint (page 48)
1 a) Zn(s) + 2HCl(aq) ZnCl2(aq) + H2(g)
b)
c)
d) Zinc reacts with the hydrogen ions in the acids.
Sulphuric acid is a dibasic acid while hydrochloric acid is a monobasic acid.
Therefore 2 mol dm–3 sulphuric acid has a higher concentration of hydrogen ions than 2 mol
dm–3 hydrochloric acid. The time required for the reaction between zinc and 2 mol dm–3
sulphuric acid to complete was shorter than that for Experiment 1.
2 a) As the reaction proceeds, the concentration of iodine in the reaction mixture decreases.
Hence the brown colour intensity of the reaction mixture also decreases.
Suggested answers to in-text activities and unit-end exercises 1 © Jing Kung. All rights reserved.Topic 10 Unit 37
New 21st Century Chemistry
b)
Checkpoint (page 53)
a)
b)
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New 21st Century Chemistry
c)
d)
Checkpoint (page 60)
1 • Increase the concentration of the reactant in aqueous solution.
This increases the number of reactant particles per unit volume. The particles are more
crowded. The chance of collision increases and the number of effective collisions increases.
Hence the rate of the reaction increases.
• Use powdered solid reactant instead of lumps of solid reactant.
This increases the contact surface area between the solid reactant and the reactant in aqueous
solution. There is a greater chance for collision and the number of effective collisions
increases. Hence the rate of the reaction increases.
• Increases the temperature.
The reactant particles have more energy and collide more often. Besides, a larger portion of
the particles have energy equal to or greater than the activation energy. So, there are more
effective collisions and the rate of the reaction increases.
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New 21st Century Chemistry
2 a) The red line indicates the concentration of X(g).
The black line indicates the concentration of Y(g).
The orange line indicates the concentration of Z(g).
b) The time would be longer.
In a larger container, the concentrations of the reactants become smaller. The chance of
collision decreases and hence the rate of the reaction decreases.
Library Search & Presentation (page 64)
Heterogeneous catalyst and homogeneous catalyst
There are two large groups of catalyst:
• heterogeneous catalyst (where the catalyst and the reactants are in different phases); and
• homogeneous catalyst (where the catalyst and the reactants are in the same phase).
By far the most important catalysts are the heterogeneous catalysts. The market share of
homogeneous catalystsis estimated to be only 10 – 15 %.
Examples of uses of heterogeneous catalysts
Methanol synthesis
The synthesis of methanol from CO and H2 has been known since the early 1920s.
CO(g) + 2H2(g) CH3OH(g) ΔH < 0
The high pressure process is carried out with ZnO / Cr2O3 catalyst at 250 – 350 atmospheres and
350 – 400 °C. The development of more active, copper-based catalysts allowed the process to be
carried out in the pressure range 50 – 100 atmospheres and at lower temperatures. This improved
the economics of the process. The low pressure process was introduced in the mid-1960s.
Methanol synthesis is carried out in a recycle process similar to ammonia synthesis. The strong
temperature dependence of the methanol equilibrium and the increasing extent of side reactions at
higher temperature require rapid heat removal or cooling by introduction of fresh gas. Methanol
plants are usually operated at a partial conversion of 15 –18 % of the CO starting material with
recycle of the unchanged synthesis gas. Large quantities of gas must be circulated.
Alkene polymerization
The polymerization of alkenes has been carried out industrially for decades and can be performed
by various mechanisms. The high pressure radical addition polymerization of ethene leads to low
density polythene (LDPE).
In the mid-1950s Ziegler achieved the low pressure polymerization of ethene and propene (up to 10
atmospheres, 50 – 150 °C) by using organometallic catalysts based on TiCl4 / Al(C2H5)3. The
Ziegler catalysts give less branched, linear high-molecular polythene (high density polythene,
HDPE). Using this catalyst system, Natta succeeded in manufacturing crystalline, isotactic
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New 21st Century Chemistry
polypropene, and around the same time, the company Phillips in the USA developed silica-
supported chromium catalysts. Oxides of Cr and Ti on various support materials have high activities
for the polymerization of ethene to HDPE.
Catalytic carbonylation
The formation of C–C bonds is of key importance in organic synthesis. An important catalytic
process for generating C–C bonds is provided by carbonylation (carbonylation refers to reactions
that introduce carbonyl group into an organic compound).
For example, in the Celanese process, ibuprofen is produced by carbonylation of a substituted
alcohol according to the following equation:
•
Hoffmann La Roche has developed a process for the anti-Parkinsonian drug, lazabemide, by
amidocarbonylation of 2,5-dichloropyridine. This one-step route has replaced an original synthesis
that involved eight steps.
Zeolite catalysts in the petrochemical industry
Zeolites are crystalline aluminosilicates composed of SiO44– and AlO45– tetrahedra arranged in
various geometric patterns. The tetrahedra are lined together at the corners by shared oxygen atoms
to form ordered lattices, which are often best visualized as three-dimensional combinations of
chains, layers, and polyhedra.
Because of their unique porous properties, zeolites are used in a variety of applications. Processes based on
zeolite catalysts were first developed in the 1960s.
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New 21st Century Chemistry
Cracking
Before cracking, liquid fractions from the fractional distillation of petroleum are re-vaporized
before cracking. Zeolite catalysts are used in the cracking process.
Isomerisation
Hydrocarbons used in petrol are given an octane rating which relates to how effectively they
perform in the engine. A hydrocarbon with a high octane rating burns more smoothly than one with
a low octane rating.
Molecules with straight chains have a tendency to undergo pre-ignition. When the petrol / air
mixture is compressed they tend to explode, and then explode a second time when the spark is
passed through them. This double explosion produces knocking in the engine.
Octane ratings are based on a scale on which heptane is given a rating of 0, and 2,2,4-
trimethylpentane a rating of 100.
In order to raise the octane rating of the molecules found in petrol, the oil industry rearranges
straight chain molecules into their isomers with branched chains.
One process uses a platinum catalyst on a zeolite base at a temperature of about 250 °C and a
pressure of 13 – 30 atmospheres. It is used particularly to change straight chains containing 5 or 6
carbon atoms into their branched isomers.
References:
Jens Hagen (2006) Industrial catalysis. WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim,
Germany.
http://www.cheresources.com/zeolitezz.shtml
http://www.chemguide.co.uk/physical/catalysis/petrochem.html
http://www.chemheritage.org/discover/chemistry-in-history/themes/petrochemistry-and-synthetic-
polymers/petrochemistry/weisz.aspx
STSE Connections (page 66)
1 Airbags had been designed based on car occupants of average size, so the force and direction of
impact of the bag itself could hurt children or small adults.
Car manuals say young children should not be put in front seats where they might be injured or
killed by an inflating airbag.
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New 21st Century Chemistry
2 The second-generation airbags deploy with less force. Reuters reports that second-generation
airbags are less risky for children while still providing appropriate levels of safety for larger
adults.
Manufacturers are actively developing ‘smart’ airbags that are able to tailor deployment based
on crash severity, occupant size and position, or seat belt use. These bags should eliminate the
risks produced by current airbag designs.
Another direction of the development of airbag is to protect the pedestrians. One team of British
experts has developed a new external airbag for pedestrians. The system deploys a bonnet-
mounted airbag at the base of the windscreen, which research shows is where a pedestrian’s
head is most likely to hit. The system uses radar and infrared technology to ‘pre-detect’ a
collision and inflates quickly enough to cushion the impact.
References:
Erin Mays (2006). Second generation air bags safer for kids, still safe for adults.
Retrieved July 8, 2009, from
http://www.autoblog.com/2006/07/12/university-of-washington-study-shows-airbags-with-reduced-
risks/
IHS Automotive, Airbags — The Next Generation
Retrieved July 8, 2009, from
http://auto.ihs.com/news/newsletters/atuo-v4i2-03.htm
Ben Mack (2009). External airbag designed to protect pedestrians.
Retrieved July 8, 2009, from
http://www.wired.co.uk/news/archive/2009-05/05/external-airbag-designed-to-protect-
pedestrians.aspx
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New 21st Century Chemistry
Unit-end exercises (pages 69 – 82 )
Answers for the HKCEE (Paper 1) and HKALE questions are not provided.
1 A possible concept map:
2Rate increases / remains the same /
decreasesUsing powdered calcium carbonate Rate increasesUsing an acid of higher concentration Rate increasesAdding water to the reaction mixture Rate decreasesAdding more acid of the same concentration
Rate remains the same
Raising the temperature of the acid Rate increases
3 a) Cutting whole potatoes into chips increases the surface area of potatoes, thus increases the
cooking rate.
b) Low temperatures slow down reactions that lead to the spoiling of food. Thus storing food
products in refrigerators helps keep food from spoiling.
4 a) Magnesium hydroxide (Other reasonable answers are acceptable.)
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New 21st Century Chemistry
b) Mg(OH)2(s) + 2HCl(aq) MgCl2(aq) + 2H2O(l)
c) i) Experiments 3 and 5
ii) Experiments 4 and 5
iii) Experiments 1 and 2
5 When the temperature is increased, the reactant particles gain more energy and move faster.
That means particles have more energy and collide more often.
Besides, a larger portion of the particles have energy equal to or greater than the activation
energy.
So, there are more effective collisions and the rate of the reaction increases.
6 C Option C — The rate of decomposition in Experiment I was higher because a higher
concentration of ammonium nitrite solution was used.
The volume of nitrogen collected in Experiment I was higher because a greater
amount of ammonium nitrite was used.
7 A Option A — The rate of reaction in Experiment 2 was lower when using a lower
temperature.
Option B — The rate of reaction in Experiment 2 would be higher when a higher
temperature and an acid of higher concentration were used.
Option D — The rate of reaction in Experiment 2 would be higher when an acid of higher
concentration was used.
8 D
9 D Option D — A catalyst can increase the rate of the reaction.
A catalyst does not change the amount of product formed in the reaction.
10 A
11 a) CaCO3(s) + 2HCl(aq) CaCl2(aq) + H2O(l) + CO2(g)
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New 21st Century Chemistry
b)
c) • Volume of acid
• Concentration of acid
• Temperature
d)
(Both curves finish within 5 minutes and with the same volume of gas; curve S finishes
before curve L; curve S steeper than curve M, which steeper than curve L)
e) Measure the loss in mass of the reaction mixture over a certain time interval.
12 a)
b) Curve B
At the start of the reaction, the tangent to curve B is steeper.
Therefore the initial rate of the experiment represented by curve B is higher.
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New 21st Century Chemistry
c) Hydrochloric acid was in excess because all the barium dissolved in both case (i.e. all the
barium reacted).
d) Increase the temperature.
13 a) Hydrogen gas escaped through the cotton wool.
b) To stop any acid from splashing out.
c)
d) The rate of reaction decreased with time.
At the start, there were plenty of reactant particles per unit volume.
As the reactant particles were consumed gradually, there were fewer particles per unit
volume. So, the reaction slowed down.
The reaction stopped when one of the reactants was used up.
e) i) The reaction rate decreased.
For the same mass of magnesium, the surface area of magnesium ribbon was less than
that of magnesium powder.
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New 21st Century Chemistry
ii) The reaction rate decreased.
Ethanoic acid is a weak acid while hydrochloric acid is a strong acid.
Ethanoic acid only partially dissociates in water while hydrochloric acid almost
completely dissociates.
Thus 1 mol dm–3 ethanoic acid has a lower concentration of hydrogen ions than 1
mol dm–3 hydrochloric acid.
14 a) The volume of chlorine was still increasing after 2.5 minutes.
b) The total time for the reaction is about 4.5 minutes.
c) i) The rate was the same (as the concentration of the acid remained unchanged).
ii) The rate was higher (as the temperature was increased).
15 a)Volume of 0.1 mol dm–3
Na2S2O3(aq) (cm3)Volume of
water (cm3)Volume of 0.1mol dm–3
HCl(aq) (cm3)
Reaction time (s)
100 0 5 2080 20 5 2560 40 5 3340 60 5 5020 80 5 100
b) • Mark a cross on a piece of paper.
• Put a beaker containing some sodium thiosulphate solution on top of the paper.
• Add dilute hydrochloric acid to the beaker.
• Start the stop watch at the same time. The cross gets fainter as the precipitate forms.
• Stop the stop watch when the cross can no longer be seen from above.
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New 21st Century Chemistry
c) The relative rate of reaction is inversely proportional to the time taken for enough sulphur to
form to make the reaction mixture opaque.
d) The rate of reaction increases with the concentration of sodium thiosulphate solution.
Increasing the concentration of sodium thiosulphate solution means increasing the number
of particles per unit volume. The particles are more crowded.
The chance of collision increases and the number of effective collisions increases.
16 —
17 • Carrying out the experiment three times at each temperature to obtain an average reaction
time.
• Repeating the experiment at three or four different temperatures to see if any trend could be
detected.
• More accurate temperature control — by heating the acid to the same starting temperature as
the contents of the beaker.
Other possible refinements may include:
• stirring the solutions on mixing;
• insulating the reaction mixture;
• using a colorimeter connected to a data-logger to obtain more accurate reaction times.
18 —
19 a) i) The rate of reaction increases with temperature.
ii) When the temperature is increased, the reactant particles gain more energy and move
faster. That means particles have more energy and collide more often.
Besides, a larger portion of the particles have energy equal to or greater than the
activation energy.
So, there are more effective collisions and the rate of the reaction increases.
b) i) There is no sodium hydrogencarbonate / citric acid. No carbon dioxide is released.
ii) Any one of the following:
• Fizzing breaks up the tablets.
• Fizzing stirs up the reactant particles.
• Fizzing increases the contact between the reactant particles.
iii) Pain-killer is only absorbed when it enters the blood stream in solution form.
Head-Kleer tablets take longer to dissolve in the stomach.
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New 21st Century Chemistry
c) Number of moles of citric acid =
= 4.2 x 10–3 mol
According to the equation, 1 mole of C6H8O7 reacts with NaHCO3 to give 3 moles of CO2.
i.e. number of moles of CO2 produced = 3 x 4.2 x 10–3 mol
= 1.26 x 10–2 mol
Mass of CO2 produced = 1.26 x 10–2 mol x 44.0 g mol–1
= 0.55 g
20 a) Enzyme is a protein-based catalyst.
b) By measuring the volume of oxygen evolved at regular time intervals. / By measuring the
pressure inside a closed reaction vessel at regular time intervals.
c) When the temperature was increased, the particles gained more energy and moved faster.
The particles had more energy and collided more often.
Besides, a larger portion of the particles had energy equal to or greater than the activation
energy.
So, there were more effective collisions and the rate of decomposition increased.
d) The enzyme was denatured / destroyed.
e) Any one of the following:
• Bread; yeast
• Alcohol; yeast
• Cheese; rennet
21 a) Control experiment
No oxygen gas produced
b) 2 cm3 of liquid were injected.
c) To keep the total volume of the reaction mixture constant
so that the volume of H2O2 used is proportional to its concentration in the reaction mixture.
d) The volume recorded is the volume of oxygen produced in 15 s
which is proportional to the amount of H2O2 used up in 15 s.
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0.80 g192.0 g mol–1
New 21st Century Chemistry
e) The rate of reaction increases, then remains constant.
22 a) When carbon monoxide and oxides of nitrogen pass through the catalytic converter, carbon
dioxide and nitrogen are formed by the catalytic action of rhodium (Rh).
Rh
2CO(g) + 2NO(g) 2CO2(g) + N2(g)
Platinum (Pt) catalyzes the oxidation of carbon monoxide and unburnt hydrocarbons (e.g.
octane) to carbon dioxide and water.
Pt
2CO(g) + O2(g) 2CO2(g)
Pt
2C8H18(l) + 25O2(g) 16CO2(g) + 18H2O(l)
b) Lead compounds stop the catalyst working.
23 a) Fruits are slightly acidic.
b) i) When the temperature is increased, the reactant particles gain more energy and move
faster. That means particles have more energy and collide more often.
Besides, a larger portion of the particles have energy equal to or greater than the
activation energy.
So, there are more effective collisions and the rate of the reaction increases.
ii) The enzyme is denatured / destroyed.
c) Any one of the following:
• Fruit is contaminated.
• Enzyme in fruit is harmful.
• Quality of fruit is affected.
• Taste of fruit is affected.
24 To determine the rate of the reaction between magnesium and excess dilute hydrochloric acid,
we can measure the volume of hydrogen produced.
Place a plastic bottle of dilute hydrochloric acid and a piece of magnesium ribbon in a conical
flask (do not mix the two chemicals yet). Insert the stopper plus a gas syringe.
Tilt the bottle containing the hydrochloric acid to mix the acid with the magnesium ribbon. Start
the stop watch at the same time. Record the volume of hydrogen produced every 30 seconds
until the reaction stops.
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New 21st Century Chemistry
Repeat the experiment with the same volume of hydrochloric acid of different concentrations.
The more concentrated the acid, the less time it takes to complete the reaction. That means the
reaction with a more concentrated acid is faster than that with a less concentrated acid.
To carry out a fair test, control the variables (such as the mass of magnesium ribbon used, the
temperature of the acid) so that only the concentration of hydrochloric acid varies.
25 Mark a cross on a piece of paper.
Put a beaker containing 50 cm3 of sodium thiosulphate solution on top of the paper.
Add 5 cm3 of dilute sulphuric acid to the beaker. Measure and record the initial temperature of
the reaction mixture.
Start the stop watch at the same time. The cross gets fainter as the precipitate forms.
Stop the stop watch when the cross can no longer be seen from above. Record the time (t)
taken.
Measure and record the final temperature of the reaction mixture.
Heat four beakers of 50 cm3 of sodium thiosulphate solution to about 35 °C, 45 °C, 55 °C and
65 °C respectively.
Repeat the experiment with these solutions.
The time (t) taken to reach such the opaque stage is inversely proportional to the average rate
of reaction from the start to the opaque stage.
From the experimental data, it can be concluded that the average rate of reaction between
sodium thiosulphate solution and dilute sulphuric acid increases when the temperature is
increased.
(Other experiment for investigating the effect of temperature on reaction rate is acceptable.)
When the temperature is increased, the reactant particles gain more energy and move faster.
That means particles have more energy and collide more often.
Besides, a larger portion of the particles have energy equal to or greater than the activation
energy.
So, there are more effective collisions and the rate of the reaction increases.
Suggested answers to in-text activities and unit-end exercises 16 © Jing Kung. All rights reserved.Topic 10 Unit 37