Chapter 4 Glossary PDF

Summary

This document provides a glossary of terms related to chemistry. The definitions cover various concepts, including chemical processes, radioactive elements, and biological terms.

Full Transcript

CHAPTER

3 Glossary
incomplete combustion: radiation sickness: a condition that results from a
combustion that occurs when large dose of ionising radiation, causing significant
oxygen is limited; produces cell death; symptoms include nausea, vomiting, fever,
carbon (soot, smoke) and hair loss and diarrhoea
carbon monoxide, and does not radioactive: emitting radiation
release as much heat or light as radioisotope: an isotope with a nucleus that may
complete combustion incomplete combustion undergo a nuclear reaction
ionising radiation: any form radiotherapy: a cancer treatment in which tumours
of radiation that has the ability to remove electrons are exposed to high concentrations of radiation
from atoms and molecules
reactants: chemicals that take part in a chemical
isotopes: atoms that have the same number of reaction; they are written on the left-hand side of the
protons but a different number of neutrons arrow
law of conservation of mass: atoms are not created respiration: a series of chemical reactions that
or destroyed in a chemical reaction; they can only be releases energy from glucose; it takes place in the
rearranged mitochondria inside cells
mitochondria: organelles in rust: hydrated iron(III) oxide; chemical formula
plant and animal cells where Fe2O3.H2O
respiration takes place
salt: the term commonly used for sodium chloride,
mutation: a change in the but which covers any compound formed by a metal
DNA of a cell that causes it taking the place of the hydrogen atom in an acid
to change how it works and mutation
stable nuclei: nuclei that will never undergo a
reproduces
nuclear reaction
neutralisation: a reaction of an
stomata: microscopic holes in the leaves of plants
acid with a base, forming a salt and
where gases such as oxygen, carbon dioxide and
water
water vapour can enter or exit the plant
nuclear decay: when a nucleus
tarnish: a black coating of silver sulfide that is
undergoes a nuclear reaction and
produced when silver reacts with sulfur in food or
emits radiation
neutralisation the atmosphere; chemical formula Ag2S
nuclear radiation: rays or particles
transmutation: a nuclear
that are emitted by a nucleus during
reaction that converts one proton

a nuclear reaction
type of atom into a different Na Ne

nuclear reaction: a process that causes a nucleus to type of atom
change, including alpha decay, beta decay, fission transmutation
unstable nuclei: nuclei that
and fusion
may undergo a nuclear reaction at any time
photosynthesis: endothermic reaction that takes
verdigris: a green coating of copper hydroxide that is
place in green plants; uses energy from sunlight to
produced when copper reacts with moisture, carbon
combine water and carbon dioxide and produce
dioxide and oxygen in the atmosphere; chemical
glucose and oxygen gas
formula Cu(OH)2
products: chemicals produced in a
word equation: simple written description of what is
chemical reaction; they are written
happening in a reaction
on the right-hand side of the arrow
radiation burns: redness and
blistering on the surface of the skin
or other organs caused by intense
exposure to ionising radiation radiation burns
AB
3.11

CHAPTER 3 REACTION TYPES 123
4
CHAPTER

Heat, sound and light
Have you ever wondered...
why a doona keeps you warmer than just a
sheet?
why tiles feel colder than carpet?
how musical instruments make different
sounds?
why you cannot see clearly underwater?
LightbookStarter
why diamonds sparkle?
LS LS

After completing this chapter you should be able to:

discuss how the wave and particle models explain how energy is transferred
outline how energy moves differently, depending on the material it passes
through
investigate the transfer of heat through convection, conduction and radiation
use the particle model to explain conduction and convection
identify safe sound levels for humans and how this affects leisure
and the workplace.
This is an extract from the Australian Curriculum AB
4.1
Victorian Curriculum F–10 © VCAA (2016); reproduced by permission

124
 MODULE

4.1 Heat
In cold weather, you seek extra jumpers
or thicker doonas to keep warm. When it
is really hot, you wear less clothing and
cool yourself with a fan or by jumping in
the pool. Heat is a form of energy that you
sense through receptors in your skin. Heat
is lost from your skin as you stand in front
of a fan and is gained as your body absorbs
radiant heat from the flames of a log fire.

science 4 fun
Burning a balloon!
Can you heat water in a balloon without NO 4 Now hold another balloon
bursting the balloon? under a tap and fill it up with
Collect this … water to about the size of a
rockmelon.
two balloons
matches 5 Place a lit candle underneath
this second balloon, and
candle
again observe what happens.
Do this …
Record this …
1 Blow up a balloon and tie its end.
1 Describe what happened.
2 Hold a lit candle below the balloon.
2 Explain why you think this happened.
3 Observe what happens.

The particle model The particles of a gas are not bound together at all
and are free to move in straight lines until they collide
Heat is a form of energy that can be transferred with other gas particles, or the walls of the container
through solids, liquids and gases. To understand how in which they are held. Particle model diagrams for a
this happens, you first need to understand the particle solid, a liquid and a gas are shown in Figure 4.1.1.
model of matter. In the particle model, atoms are
considered as small, hard balls.
In a solid, the particles are closely packed. The particles
vibrate on the spot but keep the shape of the substance
they form. Particles in a liquid are packed closely
together too. The particles vibrate but are also free to
move or flow over each other.

solid liquid gas

FIGURE 4.1.1 Particle model diagrams for a solid, a liquid and
a gas

CHAPTER 4 HEAT, SOUND AND LIGHT 125
 Heating substances Temperature
Heating a substance adds energy to its particles. Some Temperature can be measured using a thermometer.
of this energy is stored in the material itself as potential A thermometer contains a liquid (alcohol or mercury)
energy. The remaining heat energy increases the kinetic inside a narrow glass tube. This liquid expands when
energy of the particles in the material. Kinetic energy heated and contracts when cooled. Temperature is read
is the energy of movement. So if the temperature of from a scale on the thermometer corresponding to the
a substance increases, then its particles move faster expansion or contraction of the liquid. Temperature is
and faster. This spreads the particles further apart and commonly measured in degrees Celsius (°C).
the substance expands. Similarly, particles lose kinetic The Fahrenheit (°F) and kelvin (K) scales are also used
energy when the temperature decreases. The particles to measure temperature. The three scales are compared
slow down and the substance contracts. Figures 4.1.2 in Figure 4.1.4.
and 4.1.3 show what happens when a solid and a gas is
heated or cooled. boiling
point of
When sufficient heat energy is added to a solid or a water 212°F 100°C 373 K
liquid, the particles break free from each other and the
substance changes state and melts or evaporates.

freezing
point of
water 32°F 0°C 273 K

absolute
zero –459°F –273°C 0K

Fahrenheit Celsius Kelvin
scale scale scale

FIGURE 4.1.4 The three scales commonly used to measure
temperature

hot

expansion

contraction
FIGURE 4.1.2 The particles in a solid
vibrate more when heated. This causes the cold
solid to expand.

hot

expansion

FIGURE 4.1.3 The particles of a gas travel
contraction
faster when heated. They hit the sides of the
container more frequently and with more cold
force. A balloon has flexible walls so this
force will cause it to expand.

126 PEARSON SCIENCE 9 2ND EDITION
The temperature of a substance is a measure of the
average kinetic energy of its particles. The particles Heat flows from the
warmer hands into
of hotter substances move faster than the particles of
the ice.
cooler substances. As the temperature drops, particles
lose kinetic energy. Eventually the particles barely
move at all. This happens at –273°C, at a point called
absolute zero.
Thermometers measure temperature but do not
measure the heat of a substance. Heat is a form of
energy and is a way of describing the total energy of all
particles within an object. For example, saucepans A
and B in Figure 4.1.5 both contain boiling water. Their
temperatures are equal. However, saucepan B contains Heat flows from
twice the volume of water and so it has twice the heat the hotter cup
into the hands.
energy of saucepan A.

Saucepan A
100°C

fewer particles
less energy overall
FIGURE 4.1.6 Heat flows from your hands into an ice block,
Saucepan B
and from a hot cup into your hands.
100°C

Hotter substances have faster moving particles
more particles than particles in cooler substances. For example,
more energy overall the particles in a cup of hot coffee vibrate rapidly
because of its temperature. If a metal spoon is put
into the coffee, then the particles of the spoon vibrate
FIGURE 4.1.5 The amount of boiling water in saucepan B is faster too. This spreads the heat through the spoon
twice that in saucepan A. For this reason, saucepan B has twice
and increases the temperature of the spoon, making
the energy.
it hot to touch.This process of heat transfer by
vibrating particles is called conduction and is shown
Heat transfer in Figure 4.1.7.
Heat flows from areas of higher temperature to areas
of lower temperature. The greater the temperature
difference, the faster the flow of heat from one object
to another. This process of heat transfer can happen in Vibrations pass energy on.

three ways: conduction, convection and radiation.

Conduction
Hold an ice block and your hands get cold. This is
because heat flows from your skin into the ice, lowering
the temperature of your skin in the process.You know that Heat is conducted in this direction.
the ice cube is absorbing this heat because it starts to melt.
Heat has flowed from a high temperature (your hands)
to a lower temperature (the ice block). This is shown
in Figure 4.1.6. Likewise, when you grip a hot cup, FIGURE 4.1.7 Particles near the flame vibrate more as they
heat flows from the cup into your hands warming them absorb heat energy. These vibrations transfer energy to conduct
heat along the solid.
up—the cup is at a higher temperature than your hands.

CHAPTER 4 HEAT, SOUND AND LIGHT 127
 Conductors
Some materials conduct heat well while others do
not conduct heat at all. A glass of ice-cold lemonade
feels much colder than a polystyrene cup of ice‑cold
lemonade. This is because glass is a better heat
conductor than polystyrene. As a result, heat flows
from your warm hand into the cooler glass and your
hand feels cold. When holding the polystyrene cup,
your hand is not losing heat and so it still feels warm.
Substances that transfer heat easily are known as
conductors. Metals are good conductors of heat.
This is why most saucepans are made of stainless steel FIGURE 4.1.9 Wool fibres and the fluffy polyester, down or
(Figure 4.1.8). Silver, gold, aluminium and copper cotton filling inside a ski parka trap air and help prevent heat
loss from your body.
are particularly good conductors of heat. Sometimes,
saucepans have a copper base to better conduct heat.

FIGURE 4.1.8 Metals are good conductors of heat.
FIGURE 4.1.10 These animals must
stay warm in very cold conditions.
Insulators Polar bears rely on body fat and
a thick coat of fur for insulation,
Plastic, air, cloth, cork, wood and rubber are all very and penguins have layers of fat and
poor conductors of heat, and sometimes can block feathers that they can fluff up to trap
heat transfer completely. Such substances are known more air.
as insulators. The handles of a saucepan are usually
made from insulating materials to allow you to lift them
without burning your hands. An Esky uses insulators
such as polystyrene to keep food and drinks cool. SciFile
Gases are poor conductors of heat. Air trapped by
Penguins master the cold
woollen jumpers and blankets helps to insulate your
Penguins live in some of the coldest conditions
body from losing heat. Ski parkas, doonas and sleeping on Earth. They huddle together during storms
bags are filled with cotton, feathers, wool and polyester to minimise the surface area of the flock and to
that also traps air and helps to protect you from the minimise the heat loss through conduction to the
cold (Figure 4.1.9). Similarly, animals like penguins cold air around them. Most of a penguin’s heat
and polar bears that live in cold climates have should conduct to the ice they stand on, but heat
adaptations that help them stay instead conducts from hot blood flowing through
arteries passing down their legs to the cold blood
warm (Figure 4.1.10). Prac 1 Prac 2 AB
p. 134 p. 135 4.2 flowing through veins returning from their feet.

128 PEARSON SCIENCE 9 2ND EDITION
Convection Convection explains the formation of a sea breeze
during the day and a breeze towards the sea at night.
As air is heated, its particles gain energy and move This process is shown in Figure 4.1.13. Convection also
further apart. This hot air is less dense than cool air, circulates heat in a hot water system.You can see this in
and so it is pushed upwards by cooler air around it. Figure 4.1.14.
This method of heat transfer is called convection. The
air flow it creates is called a convection current. Such
a current is shown in Figure 4.1.11, transferring heat
from an open fire.
warm air air cools
rises and drops
insulated ceiling
cool air rushes in to fill space
Warm air is Air cools left by warm air
pushed upwards. and sinks.

warmer land cooler sea

A sea breeze during the day
Fire warms air.

Cooler air flows in. air cools warm air
and drops rises

cool air rushes in to fill space
FIGURE 4.1.11 Convection currents gradually spread heat from left by warm air
the open fire through the air in a room.

Heat is transferred by convection in liquids and gases
because their particles can move around. Figure cooler land warmer sea

4.1.12 shows how liquid in a saucepan is heated by A land breeze at night
convection. Convection cannot happen in a solid
FIGURE 4.1.13 In the daytime, land heats up more quickly
because the particles can only vibrate and cannot move
than the sea. Hot air is pushed upwards by cooler air that flows
freely like they do in a liquid or gas. in towards it, producing a sea breeze. At night, the sea stays
warmer for longer than the land and the process is reversed to
Water heats by convection. produce a land breeze.

Saucepan heats
to hot taps
by conduction.
hot water rises

convection current
FIGURE 4.1.12 Particles gain heat from the hot base of the
saucepan and rise. Cooler liquid sinks down, is heated and the
cycle continues.
cold water sinks
cold water
boiler

FIGURE 4.1.14 Convection assists in circulation of water in a
hot water system.

CHAPTER 4 HEAT, SOUND AND LIGHT 129
 science 4 fun SciFile
Ups and downs! Feeling chilly?
Naked mole rats are the only mammals known
Can you see convection currents in NO to not control their body temperature. Their
action? bodies are warmed to the temperature of their
Collect this … burrows, about 30°C.
dried beans, such as borlotti beans or
chickpeas
Bunsen burner, gauze mat, tripod and
bench mat
large beaker of water
Do this …
1 Add dried beans to cover the base of
the beaker.
2 Cover the beans with water and then heat
the mixture carefully over a Bunsen burner.
3 Turn off the heat after you have observed
the behaviour of the beans in the hot water.
Record this …
1 Describe what happened.
2 Explain why you think this happened.
beaker

water
beans
gauze FIGURE 4.1.15 Radiation from the Sun travels through the
mat vacuum of space to reach us. It is cooler in the shade because
tripod place this radiation has been blocked.
Bunsen
burner The hotter something is, the more heat it radiates. For
off-centre
example, a hot oven radiates more heat than an oven
bench mat
set at a lower temperature. Similarly, the red-hot coals
of an open fire radiate such enormous amounts of heat
that you cannot sit too close to them (Figure 4.1.16).

Radiation
When you go outside and into the sunlight, you can
feel the heat from the Sun on your skin (Figure 4.1.15).
Heat has travelled through empty space between
the Sun and the Earth to reach you. It cannot be
transferred by conduction or convection on its journey
because there are no particles to vibrate or flow in the
vacuum of space. The Sun transfers its heat energy
through a process called radiation.
FIGURE 4.1.16 You can feel the radiant heat emitted from the
Radiation transmits heat as invisible waves that travel
glowing coals of an open fire.
at the speed of light, which is around 300 000 km/s.
Infrared radiation is heat energy that is transmitted When radiated energy hits a surface, the heat may
this way. All objects emit (release) some infrared be absorbed into the surface, reflected from the
radiation. surface or transmitted through the surface.

130 PEARSON SCIENCE 9 2ND EDITION
This is shown in Figure 4.1.17. Often radiation will be
partially absorbed, reflected or transmitted according to SciFile
the material and its colour.
Home insulation
Dark colours Light colours Clear materials, such
absorb reflect radiated as glass, transmit
Heat transfer in a home occurs by conduction,
radiated heat. heat. radiated heat. convection and radiation. In winter, warm air
flows out of the house, and in summer, warm air
flows in. Insulation added to the ceiling and walls
of a home helps to stop this transfer of heat and
makes your home more energy efficient.

absorption reflection transmission

FIGURE 4.1.17 When radiation hits an object, it may be
absorbed, reflected or transmitted.

For example, a dark-coloured car heats up more
quickly in sunlight than a lighter-coloured car. This
happens because dark-coloured objects absorb most
of the radiation that fall on them. This means that they
STEM 4 fun
absorb much of the heat falling on them from the Sun. Insulated ice cube
Solar pool heaters and hot solar hot water systems use
PROBLEM
black tubes and collection panels to absorb as much
How long can you keep an ice cube frozen?
radiant heat from the Sun as possible (Figure 4.1.18).
Lighter coloured objects reflect much of the radiation SUPPLIES
frozen ice cube
falling on them—most of the heat that
plastic cup
falls on them is reflected and so they Prac 3 AB
p. 136 4.3 assortment of items as possible insulation
don’t heat up as rapidly. materials including cotton balls, polystyrene,
aluminium foil, rags, petroleum jelly, etc.
PLAN AND DESIGN Design the solution: what
to hot
water
information do you need to solve the problem?
taps radiation Draw a diagram. Make a list of materials you
from Sun will need and steps you will take.
CREATE Follow your plan. Draw your solution
to the problem.
IMPROVE What works? What doesn’t? How
do you know it solves the problem? What could
work better? Modify your design to make it
cold better. Test it out.
water
roof REFLECTION
1 What field of science did you work in today?
Are there other fields where this activity
applies?
2 In what career do these activities connect?
3 What did you do today that worked well?
FIGURE 4.1.18 Heat energy radiated by the Sun is absorbed by What didn’t work well?
the cold water within the black collection panels of a solar hot
water system.

CHAPTER 4 HEAT, SOUND AND LIGHT 131
 LightbookStarter
MODULE

4.1 Review questions LS LS

Remembering 9 You lose a lot of heat from your head. For most
people, their hair protects them from losing
1 Define the terms:
too much heat from their heads. Why is hair an
a temperature b conduction effective insulator?
c insulator.
10 You walk barefoot on carpet in the living room
2 What term best describes each of the following? of your house and your feet feel warm, yet when
a the temperature at which particles barely you walk into the bathroom and stand on the
move at all ceramic tiles your feet feel cold. The carpet and
b heat transfer involving particles that are free tiles are at the same temperature. Explain why
to move the carpet and the tiles feel so different.
c cool air that flows from above a body of
water towards land during the daytime. Applying
11 Use the particle model to explain why the
3 What is the temperature that water freezes on the
following expand when heated.
following scales?
a a solid metal rod
a Fahrenheit  b Celsius  c kelvin.
b a balloon.
4 Fill in the following statements with the term that
makes them true. 12 Heat transfer can occur by conduction,
a Heat always flows from an object of higher/
convection or radiation. Identify the main
lower temperature to one of lower/higher method of heat transfer in each situation below.
temperature. a Your feet get hot when you walk on sand at
the beach.
b Insulators are good/poor conductors of heat.
b Your back feels warm when you sit in the sun.
c Gases are good/poor conductors of heat.
c You boil water in an electric kettle.
d On a warm day, a house is warmer upstairs
because of conduction/convection currents. d You feel cold when you dive into a
swimming pool.
5 In the science4fun on page 130, the beans moved
e You feel warm air as you walk into a school
about the beaker because of the transfer of heat.
disco held in a hall.
Was the heat transfer an example of conduction,
convection or radiation? Analysing
Understanding 13 What is the difference between heat and
temperature?
6 Group the following objects as either conductors
of heat or insulators. 14 Two identical bathtubs are filled to the same level
a a gold wedding ring with water. The particles in bathtub A move with
b a polystyrene cup
greater speed than the particles in bathtub B.
Analyse this situation to answer the following.
c a metal seatbelt buckle
a Which bathtub will have warmer water?
d an aluminium fence
b Which bathtub will have more heat energy?
e thermal underwear.
c As the water cools, each bath loses heat
7 Describe how the motion of particles in a solid energy. List three places this heat energy
change as the solid is heated. could go.
8 A wetsuit traps a thin layer of water between the
wearer and the neoprene fabric of the suit.
a State whether water is a good or poor
conductor of heat.
b How does the wetsuit keep the wearer warm?

132 PEARSON SCIENCE 9 2ND EDITION
 MODULE

4.1 Review questions
15 Water absorbs a large amount of heat energy for 19 Sonja and Marcos are testing the insulating
a relatively small rise in temperature compared to properties of cup A and cup B in their science
other substances. Use this information to analyse laboratory. After testing, they plot the graph
why in the science4fun on page 125 the balloon shown in Figure 4.1.20.
does not burn when filled with water. Cooling of cups A and B
90
Evaluating 80

Temperature (degrees celsius)
16 On a hot day, you have a choice of travelling in a
70
red car, a white car or a black car, all of the same
60
model. All have been parked in the sunlight for
three hours. 50

a Which car would you choose? 40
Temperature cup A
b Justify your choice. 30
Temperature cup B
17 Pyrex glass expands less than ordinary glass 20

when heated. Use this information to propose a 10
reason why Pyrex is used in cooking instead of 0
ordinary glass. 0 1 2 3 4 5 6 7 8 9 10
Time (minutes)
18 Figure 4.1.19 shows the experimental
FIGURE 4.1.20
set-up for a radiation experiment. The
same-sized black and white cardboard squares a What procedure do you think the students
are attached to two thermometers close to an used in their experiment?
incandescent globe. b What is the independent variable being
a What do you think the student is trying to tested?
test in this experiment? c What is the dependent variable that Sonja
b State three variables that must be controlled and Marcos are measuring in this task?
to ensure a fair test. d To be a fair test, which variables would
c Predict which thermometer will show the Sonja and Marcos need to control in this
highest reading after 5 minutes. experiment?
d Discuss reasons for your answer to part c. e What is the initial temperature of the
contents of cup A and cup B?
f Describe how the temperature of this liquid
varied over the 10 minutes in cup A and
cup B.
g Assess which cup is the better insulator.

Creating
20 Create a short story in which you imagine that
you are one of the beans that was heated in
the science4fun on page 130. Describe how
your temperature and movement change as the
beaker is heated. For at least four stages of your
motion, add illustrations showing where you are
FIGURE 4.1.19 positioned inside the beaker.
21 a  onstruct a diagram of a new type of suit
C
that will keep you warm in cold conditions.
b On your diagram, label what the suit is made
from and how it keeps the heat in.

CHAPTER 4 HEAT, SOUND AND LIGHT 133
 MODULE

4.1 Practical investigations
1 Comparing materials metal
icy-pole spoon
Purpose plastic stick
To compare how well plastic, wood and metal spoon
conduct heat.
Hypothesis
Which do you think will conduct heat better—a
plastic spoon, a wooden stick or a metal spoon?
Before you go any further with this investigation,
write a hypothesis in your workbook.
Timing 30 minutes hot
water
Materials
butter
SAFETY
very hot water
(from a kettle) Handle hot water
FIGURE 4.1.21
with care.
plastic spoon
metal spoon
Results
wooden icy-pole stick
Record all results in your results table.
250 mL beaker
Time taken to drop (seconds)
small beads or similar
stopwatch Bead on Bead on Bead on
ruler plastic spoon icy-pole stick metal spoon

Procedure
1 In your workbook, construct a results table like Review
the one in the Results section.
1 Which of the materials used was the best
2 Put a dob of butter near the top of the handle of conductor of heat?
the plastic spoon.
2 Assess whether or not your hypothesis was
3 Push a bead onto the dob of butter. correct.
4 Repeat steps 1 and 2 for the metal spoon and 3 Which material was the best insulator?
icy-pole stick. Make sure the beads are placed at
4 Explain why it was important to place the beads
equal heights and that the same amount of butter
at the same height, and use the same amount of
is used each time.
butter.
5 Carefully place the spoons and the icy-pole stick
5 The thermal conductivity of a material is a
into very hot water in the beaker as shown in
measure of how well the material conducts heat.
Figure 4.1.21.
It has the unit watts per metre kelvin (W/m/K).
6 Time how long each bead takes to fall off, and The higher this value is, the better the substance
record your results in a table like the one shown conducts heat.
in the Results section.
Use your results to identify which of the following
thermal conductivities belong to the plastic spoon,
the metal spoon and the wood icy-pole stick.
0.17 16.0 0.19

134 PEARSON SCIENCE 9 2ND EDITION
 MODULE

4.1 Practical investigations
2 Testing insulators 2 Carefully measure 200 mL of hot water using a
beaker, and pour this into your can.
Purpose
3 Place the can inside the box.
To test how effective different materials are in
4 Record the initial (starting) temperature of
insulating heat.
the water, and then measure and record the
Hypothesis temperature every 2 minutes for 10 minutes.
Which of the materials that you have available Record all your measurements in a table like that
for this prac do you think will keep water in a can shown below.
the warmest? Before you go any further with this 5 Repeat, using water at the same initial
investigation, write a hypothesis in your workbook. temperature and packing one of the insulating
Timing 60 minutes materials into the space between the can and the
box, as shown in Figure 4.1.22.
Materials
6 Repeat the process, using a second insulating
a range of insulating materials, such as newspaper
strips, cloth, cotton wool, foam, polystyrene material.
beads, foam packing bullets, fibreglass insulation,
carpet scraps aluminium can thermometer
with 200 mL water
insulating
thermometer or material
temperature probe SAFETY cardboard box

cardboard box Handle hot water
hot water with care.
beaker
stopwatch or clock
empty soft-drink cans FIGURE 4.1.22

You may use a temperature probe to gather
temperature data.
Procedure Results
1 In your workbook, construct a table like 1 In your results table, insert the names of two
that shown below. Alternatively, construct a insulating materials you are going to test.
spreadsheet with similar columns to those in 2 Record all measurements in your table or
the table. spreadsheet.
3 Construct a line graph of temperature versus
time for each sample tested, to show the
Water temperature
temperature drop over time. Alternatively, use
Time Water temperature (°C) data-logging equipment to produce a graph.
(minutes)
Can with no Can with Can with Review
insulating insulating insulating
materials (air only) material A material B 1 a Construct a conclusion about which material
was the best insulator.
0
b Assess whether your hypothesis was
2 supported or not.
4 2 Why was it important to test one can with no
6 insulating materials?
3 Identify any sources of error in your experiment.
8
4 Outline any improvements that could be made to
10
the design of the experiment.

CHAPTER 4 HEAT, SOUND AND LIGHT 135
 MODULE

4.1 Practical investigations
STUDENT DESIGN

3 Comparing heat radiation
Purpose Hints
To compare how silver, white and black cans radiate Make sure:
heat. your cans all contain the same amount of
water
Hypothesis
the water is at the same starting temperature.
Which colour aluminium can do you think will
Use the STEM and SDI template in your eBook
radiate more heat over time—silver, white or black?
to help you plan and carry out your investigation.
Before you go any further with this investigation,
write a hypothesis in your workbook. Results
Timing 45 minutes 1 Write a report on your findings.
Materials 2 Construct a line graph to display your results.
SAFETY Review
silver, white and black
aluminium cans A risk assessment
1 Evaluate your procedure. Pick two other prac
is required for this
thermometer or investigation. groups and evaluate their procedures too,
temperature probe Be careful when identifying their strengths and weaknesses.
handling hot liquids. 2 a Construct a conclusion for your
Procedure
investigation.
1 Design an investigation to compare the amount
b Assess whether your hypothesis was
of heat that is radiated over time from silver,
supported or not.
white and black aluminium cans.
2 Brainstorm in your group and come up with
several different ways to investigate the problem.
Select the best procedure and write it in your
workbook. Draw a diagram of the equipment you
need.
3 Before you start any practical work, assess all
risks associated with your procedure. Construct a
risk assessment that outlines these risks and any
precautions you need to take to minimise them.
Show your teacher your procedure and your risk
assessment. If they approve, then collect all the
required materials and start work.
See Activity Book Toolkit to assist with
developing a risk assessment.

136 PEARSON SCIENCE 9 2ND EDITION
MODULE

4.2 Sound
Indigenous Australians developed the
didgeridoo thousands of years ago. The player
blows air into the didgeridoo while vibrating
his lips to produce a low rumbling sound. In
addition to the didgeridoo, wind instruments
like trumpets, flutes and trombones rely
on vibrating air to make sounds. Other
instruments, like violins, pianos and guitars,
produce sound using strings that vibrate.

science 4 fun
Straw clarinets Sound waves
How does changing the length of a Sound is produced when something vibrates, moving
flute or a clarinet change the sound it back and forth very quickly. Table 4.2.1 shows some
produces? common sounds and the objects that vibrate to produce
Collect this … them. When something vibrates, it passes the vibrations
straw into its surroundings, e.g. air. These vibrations create
pair of scissors regions of space in which the air particles are bunched
Do this … together and regions in which they are more spread
1 Squash the end of the straw and cut it to out. The bunched up areas are called compressions
make a point. and the spread-out areas are called rarefactions. Both
2 Blow into the pointy end of the straw. areas are shown in Figure 4.2.1 on page 138. A sound
3 Try different positions until you get a wave is the movement of alternating compressions
buzzing sound. and rarefactions. Sound waves travel away from the
4 As you are making the sound, have a source of a sound, in the same way that ripples of water
partner carefully cut the other end of your
move outwards when a stone is dropped into a pond.
straw.
TABLE 4.2.1 Common sounds and their sources
5 Keep cutting, making the straw
shorter and shorter. Sound Vibrating source
Record this … speech folds of skin (called vocal cords)
1 Describe how the
sound changed drum drum skin
as the straw got piano string inside piano (when you strike a
shorter. key, the string is struck by a hammer)
2 Explain how you
saxophone reed inside the mouthpiece and
think the straw therefore the air inside the saxophone
produced a
sound. car stereo speaker cone
system
a bell ringing metal casing of the bell (when struck)

CHAPTER 4 HEAT, SOUND AND LIGHT 137
 Vibrating speaker air particles A sound wave differs from a transverse wave. In a
sound wave, the particles that make up the wave move
back and forth in the same direction as the wave is
travelling. This type of wave is called a longitudinal
wave, or compression wave. This type of wave is
shown in Figure 4.2.3.
direction of energy flow
Push, then
pull repeatedly compressions rarefactions
compression rarefaction
FIGURE 4.2.1 A vibrating speaker produces regions in which
air particles are squashed close together (compressions)
and regions in which air particles are spaced further apart
(rarefactions). The energy moves through air as a sound wave. coil movements wave direction

FIGURE 4.2.3 In a longitudinal wave, particles move in the
Sound relies upon vibrating particles. This means that same direction that the wave is moving.
sound can pass through solids, liquids and gases but
not through a vacuum where there are no particles. When a guitar string is plucked, it vibrates and a
Hence, sound can pass through railway tracks, water in transverse wave moves along the string. This vibrating
a swimming pool and air but not through space. string then sets up a longitudinal sound wave in the
surrounding air particles. This is the wave that carries
Types of waves the sound to our ear. The differences between these
A wave carries energy from one point to another. This waves can be seen in Figure 4.2.4.
can happen in two ways. The energy carried by waves Prac 1
p. 145
at a beach moves horizontally, but the particles making
up the wave move in a vertical direction. This is shown
Transmission of sound
in Figure 4.2.2. This vertical movement explains why Sound energy is transmitted through a material as
a boat or a seagull floating on the sea bob up and longitudinal waves. The particles of the material vibrate
down as a wave travels to the shore. This type of wave as the sound energy flows through it. If you have ever
is called a transverse wave. Radiated heat energy is been to a concert or stood near an aircraft that is taking
transferred as a type of transverse wave. off, then you will have physically felt the energy that
can be transmitted by sound waves.
The speed that sound travels through a material
depends on the qualities of the material. In general,
wave direction
if a sound wave hits a dense material, made of
lots of particles closely packed together, then the
coil movement
compressions and rarefactions will travel quickly. As a
result, sound travels faster through solids than through
FIGURE 4.2.2 In the transverse wave shown here, the particles
of the wave vibrate up and down whilst the wave travels liquids, and faster through liquids than through gases.
forward. Table 4.2.2 shows that sound travels much faster through
glass or steel than through air, the temperature of the
material also affects the speed of sound transmission.

Guitar string sound wave
compression compression compression compression
rarefaction rarefaction rarefaction FIGURE 4.2.4 The top
or crest of the transverse
wave of a vibrating guitar
string correlates to the
compression of the particles
of the longitudinal wave and
the bottom or trough of the
transverse wave correlates to
the rarefaction.

138 PEARSON SCIENCE 9 2ND EDITION
The particles of warmer materials vibrate faster than
particles in cooler materials. As a result, sound travels SciFile
faster through warm air than through cool air and faster
through warm water than through cold water. Lightning speed
TABLE 4.2.2 Speed of sound in various materials You will see the
spectacular effects of
Material Speed of sound a fireworks display
(metres/second) before you hear the
air (at 0°C)   331 explosions. This is
air (at 18°C)   342 because light travels
much faster than
water 1440
sound.
wood 4500
steel 5100
glass 5200 A bare and empty room has multiple hard surfaces
which reflect sound with little if any absorption
Reflection and absorption of (Figure 4.2.6). This causes any sound to bounce
around as a series of echoes, allowing the sound to be
sound heard for a considerable time. The length of time a
You can usually hear people in the next room if they sound can be heard for is known as reverberation.
are noisy. This happens because sound passes through Soft materials such as curtain fabric, carpet and
thin walls and is transmitted short distances through cushions absorb sound and convert it into heat. This
most materials. reduces the reverberation, or length of time a sound is
Hard surfaces, such as concrete or bathroom tiles, heard.
reflect sound waves. This reflected sound is heard
as an echo. The time difference between sending
and receiving sound waves can be measured. This
difference can be used to calculate the depth of objects
under water, using a technique called sonar (sound
navigation and ranging), shown in Figure 4.2.5.
In this process, a ship sends a sound wave into the water.
The sound wave bounces off any hard surfaces in the
water such as fish. We can calculate the depth of objects In an unfurnished
under water by measuring the time a sound wave takes room, sound reflects
from the hard surfaces
to bounce off them and return to the ship/surface. and causes echoes.

In a furnished room, sound is Acoustic material
absorbed by soft furnishings such as this can
like heavy curtains, cushions be used to absorb
and floor coverings, so there sound in buildings.
are few echoes.

FIGURE 4.2.5 Sonar can be used to determine the depth of FIGURE 4.2.6 Different materials give a room different
objects in the sea, such as this school of fish. reverberation times.

CHAPTER 4 HEAT, SOUND AND LIGHT 139
 SciFile
Boom!
Fighter jets regularly travel at supersonic
speeds—faster than the speed of sound. As
the jet catches up to and then overtakes the
sound waves it has produced, a very loud
‘sonic boom’ is heard. Sonic booms can
smash windows and damage the hearing
of humans, birds and other animals. The
sound of this jet breaking the sound barrier
has compressed water vapour in the air to
form an instantaneous cloud.

Sound absorption like this is needed in concert halls,
so that there is no overlap between the sounds being
performed and their echoes, which would otherwise microphone
distort what you hear. Figure 4.2.7 compares how well
some materials absorb sound.

Typical airborne sound absorption values
High

100
90
Low frequency
80 oscilloscope
Sound absorption

High frequency tuning
70
fork
60
Medium

50 FIGURE 4.2.8 An oscilloscope converts sound waves into
40 electrical signals that can be viewed on a screen.
30
20
Low

10
The wavelength of a sound is the distance between
0 two peaks that are next to each other. It is measured
Concrete Brick PVC Nylon Wool
acoustic tiles carpet carpet
in metres (m). A loud sound has a sound wave with
steep peaks, also known as greater amplitude. A soft
FIGURE 4.2.7 A comparison of the sound absorption levels of sound has a sound wave with smaller, less steep peaks,
different materials also known as lower amplitude. Figure 4.2.9 shows
that graphs of louder sounds have larger peaks.
Frequency and pitch
A dog has a low-pitched growl, whereas a bird chirps sound is
with a high-pitched sound. The different sounds can louder
but same
be compared by analysing their sound waves using frequency
an oscilloscope (also known as a CRO), as shown in and pitch
Figure 4.2.8.
A source that vibrates rapidly produces sound of higher
a higher pitch, than one that vibrates more slowly. frequency
reference sound and pitch
The number of vibrations a sound makes each second but sound
is called the frequency of a wave. High frequency is same
loudness
sound waves have a higher pitch, and low frequency
waves have a low pitch. Frequency is measured in FIGURE 4.2.9 A loud sound has a taller graph on an
oscilloscope than a quiet sound. Higher-frequency sound waves
hertz (Hz). Sound waves also have a wavelength. have a shorter wavelength.

140 PEARSON SCIENCE 9 2ND EDITION
 SciFile
The Doppler effect high-pitched
Have you ever heard the wail of an sound
ambulance siren rushing past? When
an ambulance travels towards you,
the sound waves of the siren bunch
up. This makes the sound of its siren
higher in pitch. As the ambulance
moves away, its sound waves are
spread further apart and the sound is
lower in pitch. This change in pitch is
called the Doppler effect, named after low-pitched sound
the Austrian physicist Christian Doppler movement
who first described it in 1842.

Louder sounds have greater amplitude than softer
sounds. The higher the frequency of a wave, the more
closely the wave is bunched together and the shorter its
wavelength.
When we get older, we lose our ability to hear higher
frequencies of sound.Young people can typically hear a
range of frequencies up to 20 000 Hz, yet most people
over 65 years cannot hear frequencies above 5000 Hz.
Hence, some mobile phone ringtones cannot be heard
by older adults. As we age, more of the tiny hair cells in
our inner ear become damaged or destroyed. This
happens most easily to the hair cells that we use to hear
high frequency sound and once they are destroyed
these cells cannot be repaired.
FIGURE 4.2.10 Ultrasound waves pass easily through fluids and
Many animals, such as dogs and cats, can hear sound soft tissue but are reflected from other layers within the body.
frequencies that are outside our human range of Echoes of these waves are detected and analysed by computer
to create the image, such as this 3D image of a human foetus.
hearing. Ultrasound is the name given to sound waves
with frequencies above our hearing range. Bats emit
ultrasound squeaks with frequencies up to 200 000 Hz,
which reflect off surfaces around them and are used by
bats to avoid obstacles and to locate food. Elephants
can hear a range of frequencies lower
than our own hearing range. These Prac 2 Prac 3
frequencies are called infrasound. p. 145 p. 146

Computer analysis of the way ultrasound reflects from
living tissue can be used to create an image, like the one
shown in Figure 4.2.10.

Musical instruments
All musical instruments produce sounds by vibrations
(Figure 4.2.11). They do this in different ways and
FIGURE 4.2.11 Each of these musical instruments uses
produce sounds of differing characteristic qualities. vibration to create its sound. Guitars use vibrating strings,
These differences can be compared by playing the trumpets use vibration from the player’s lips and air inside the
sound into a microphone attached to an oscilloscope. trumpet, and drums use a vibrating skin.

CHAPTER 4 HEAT, SOUND AND LIGHT 141
 Typical oscilloscope traces from the sound of four
instruments are shown in Figure 4.2.12. On a guitar, a Working with Science
violin and a piano, vibrations are produced by strings.
Changing the length of the string alters the frequency AUDIO ENGINEER
of the sound produced. Longer strings vibrate more Audio or sound engineers are involved in the
slowly, producing lower-pitched sound than shorter technical and mechanical aspects of mixing,
strings. When you press a string against the neck of a recording, editing and producing sound and music.
guitar, you shorten the effective length of that string. They use their skills in a wide variety of industries,
including music, film, television and radio. Audio
In percussion instruments like drums, the skin engineers work both in and out of the studio. They
stretched over the top of the drum vibrates when you are responsible for setting up audio equipment
hit it. In instruments like the triangle or the cymbal, the and performing sound checks and live sound
instrument itself vibrates. mixing at concerts, sports games and theatre
productions (Figure 4.2.13). Audio engineers also
In wind instruments, a column of air vibrates. design, develop and manufacture audio software
When you play a flute or a recorder, the length of and equipment, such as microphones and sound
this vibrating column of air is increased when you boards. More specialised audio engineers are
cover holes along the tube, and shortened when you involved in researching the science behind sound
leave the holes open. A longer vibrating column of and audio technology. There are many different
air produces a lower pitched sound than a shorter areas for audio engineers to specialise in, such as
vibrating air column. video game audio design, live sound engineering
and recording engineering.
To become an audio engineer, you will need
to complete an audio engineering and sound
production course at TAFE or university. Courses
are available from certificate level (for example,
Certificate IV in Sound Production) to degree
level (for example, Bachelor of Sound and Music
Design). Because audio engineering involves a lot
of technical skills, an interest in maths, engineering
and technology is important. Hands-on experience
guitar oboe
at a studio, community radio station or production
company is a great way to gain valuable skills and
learn how the industry works. Audio engineering
offers an interesting and diverse career pathway
and there are opportunities in a wide range of fields
for people with these skills in Australia.

piano noise

FIGURE 4.2.12 Musical notes produce a smooth, repeating
pattern on an oscilloscope. Different instruments produce
different characteristic sounds. Background noise shows as an
uneven mixture of waves.

STEM AB
p. 147 4.5
FIGURE 4.2.13 Audio engineers can work in a variety
of roles, from recording and mixing music in a studio, to
sound checks and mixing at live concerts.

Review
What kinds of recorded sounds do you hear
every day that might have been produced by an
audio engineer?

142 PEARSON SCIENCE 9 2ND EDITION
 LightbookStarter
MODULE

4.2 Review questions LS LS

Remembering 9 Predict which of the straws in the science4fun on
page 137 would produce:
1 Define the terms:
a the highest pitched sound
a compression
b sound with the longest wavelength
b transverse wave
c sound of the highest frequency.
c frequency.
10 Group the following surfaces into those that
2 What term best describes each of the following?
would reflect sound waves and those that would
a movement of alternating compressions and absorb sound waves:
rarefactions
marble tiles in a bathroom
b energy carried by the wave moves in the
polished floorboards in a school hall
same direction as the wave particles
carpet on the floor of a cinema
c distance a particle in a wave moves from its
a glass window
rest position.
a lounge room with a velvet couch and a deep
3 What is the unit used to measure the following shaggy carpet.
quantities?
a frequency Applying
b wavelength 11 Figure 4.2.14 illustrates three traces of sounds on
c speed of sound. an oscilloscope.
4 What is the speed of sound in air at 18 degrees Identify the:
Celsius? a sound with the highest frequency
5 What is the source of vibration in a flute? b sound with the lowest frequency
6 Which of the following statements are true and c loudest sound.
which are false?
a Sound is produced by vibrations.
b Regions of high air pressure are called
rarefactions.
c A sound wave can travel in a vacuum.
d Waves at the beach are called transverse A B C
waves.
FIGURE 4.2.14

Understanding
7 Explain why sound travels faster through solids
Analysing
than through liquids. 12 Analyse the oscilloscope patterns of the sound
from a guitar, oboe and piano in Figure 4.2.12
8 a What is meant by the term reverberation?
on page 142.
b Explain why an empty room is full of echoes.
a Which instrument was being played the
c Predict what happens to those echoes as loudest?
furniture, curtains and carpet are moved into
b Which instrument had the lowest pitch?
the room.
c Compare the patterns of musical instruments
with the shape of the trace that is shown for
noise.

CHAPTER 4 HEAT, SOUND AND LIGHT 143
 MODULE

4.2 Review questions
13 For the ocean wave shown in Figure 4.2.15, 15 Analyse Figure 4.2.7 on page 140 to complete
determine the: the following.
a wavelength of the wave a Which material listed best absorbs high
b amplitude of the wave. frequency sounds?
b Which material reflects the highest
i 
1.2 m proportion of sounds?
ii Propose a reason why this material does
not absorb much sound.
0.4 m
0.6 m 0.6 m
c Explain what happens to the sound energy
absorbed by materials.
16 Voice recognition uses computer programs
to identify speech. How do you think these
programs work?
FIGURE 4.2.15
Creating
14 Refer to the illustration of the air particles in a 17 Construct a diagram to contrast ultrasound with
sound wave shown in Figure 4.2.16 to complete infrasound.
the following questions.
a Determine the wavelength of this sound
wave.
b What would be the distance shown as x in
the diagram?
c Do the points marked A and B show a
compression or a rarefaction?
d Describe the difference in air pressure that
would exist at points A and B.

25 cm

A B

x
FIGURE 4.2.16

144 PEARSON SCIENCE 9 2ND EDITION
 MODULE

4.2 Practical investigations
1 Spring waves 6 Tap one end of the spring horizontally so that
a pulse travels through the spring, as shown in
Purpose Figure 4.2.17b.
To model transverse and longitudinal waves. 7 Try to draw what is happening here from a side
Timing 30 minutes view. This is a longitudinal wave, like a sound
Materials wave.
slinky spring 8 Try to alter how you produce these waves to
Procedure increase their frequency.
1 Hold one end of the slinky. A partner holds the Review
other end. Take care not to overstretch the slinky. 1 Describe how the slinky moves when a:
2 Move your end of the slinky up and down at a a transverse wave passes through
regular speed, as shown in Figure 4.2.17a. b longitudinal wave is transmitted.
3 Sketch a side view of the waves you made. These a 2 How were you able to increase the frequency of
are transverse waves, like water waves. the following waves?
4 Try to alter how you produce the waves so that a transverse waves
they are bunched closer together, with greater b longitudinal waves.
frequency. 3 Which of the two waves you produced is more
5 You and your partner hold each end still. like a sound wave?
a b

FIGURE 4.2.17

b
2 Good vibrations PART B
3 Line up the beakers (or glasses) on your bench.
Purpose
4 Fill each beaker to a different depth with water.
To investigate the differences in producing high-
5 Carefully tap the glass of each using the pen,
pitched and low-pitched sounds.
chopstick or other object, and listen to the
Timing 45 minutes variation in pitch.
Materials Review
water 1 Did the longer or shorter length of vibrating
ruler make the highest pitched sound?
5 beakers (or glasses) of the same size 2 Construct a graph that shows the difference
pen or a chopstick between sound waves produced.
ruler 3 Describe the pitch of sound produced by the
Procedure beaker with the least amount of water.
PART A 4 How do you think that the length of the ruler and
the depth of water in the beaker are related to the
1 Hold the ruler over the edge of a bench and flick
pitch of sound they produce?
it so it vibrates.
5 Do you think the vibrations would be faster or
2 Listen to how the pitch changes as you reduce
slower when producing higher pitched sounds?
the length of ruler vibrating.
6 Try and recreate a well-known tune, such as
‘Happy birthday’.

CHAPTER 4 HEAT, SOUND AND LIGHT 145
 MODULE

4.2 Practical investigations
3 Producing sound
Purpose
To see and hear the vibrations that produce a sound
vibrating tuning fork
wave.
Timing 30 minutes
Materials
water glass

selection of tuning forks
rubber mallet or rubber stopper water
100 mL beaker
wooden bench top or sounding box
Procedure
FIGURE 4.2.19
1 Strike a tuning fork with a rubber mallet or on a
soft surface such as a rubber stopper or a book. 8 Extension:
2 Place the ends of the tuning fork carefully Place two identical tuning forks in two sounding
towards your ear and see if you can hear a sound. boxes (Figure 4.2.20). Strike the first tuning
fork and carefully observe to see if the second
3 Strike the tuning fork again and this time hold it
tuning fork vibrates without being struck. This
on a bench top (Figure 4.2.18) or position it in a
phenomenon is called resonance.
hollow wooden sounding box.

rubber mallet
strikes tuning fork

FIGURE 4.2.20
FIGURE 4.2.18
Review
1 a Describe the difference you observed in the
4 Repeat the previous step using a selection of sound produced before and after the tuning
tuning forks that are designed to produce sound fork was placed on a bench top or sounding
of differing frequencies. box.
5 Half fill a beaker with water. b Propose why the sound changes in this case.

6 Strike the tuning fork and insert its ends into the 2 a Describe the effect of placing the tuning fork
water as shown in Figure 4.2.19. Observe the into the water.
water. b How can this provide evidence that the ends
of the tuning fork are vibrating?
7 Repeat the previous step but record what
happens using a phone or video camera. 3 Compare the pitch of the tuning fork with the
frequency in hertz (Hz) that is inscribed at its
base. Which tuning fork would produce a higher
pitched sound: 256 Hz or 512 Hz?

146 PEARSON SCIENCE 9 2ND EDITION
 4.2 Practical investigations ISTEM
MODULE

N Q U I RY

Energy efficient house
Background Engineering design process
You are employed by a construction firm. This firm The engineering design process is outlined in
is known for developing house designs that are Figure 4.2.22.
sustainable, energy efficient and have spaces suited Identify the purpose.
to specific needs, such as a wine cellar/cool room
Identify the independent, dependent and
and a cinema room/music studio.
controlled variables and only change one variable
A client is looking for a house design that uses the at a time.
best materials and concepts. The client is a musician Based on your purpose and the controls and
and environmentalist. Her house will be located variables, write a hypothesis for this experiment.
in an area where summer and winter weather Before you commence your investigation you
conditions are extreme. must conduct a risk assessment and write down
Problem safety measures that you will follow to keep
Your job is to provide information to the construction yourself and other students safe.
firm about energy efficient designs, materials and See Activity Book Toolkit to assist with
specific plans for specialty rooms. Using research developing a risk assessment.
then trialling materials for heat-proofing or sound- Summarise your experiment in a scientific report
proofing, you will present the firm with the best including the Purpose, Hypothesis, Materials,
des