We use waves to
transfer energy and
transfer information
Transverse waves vibrate at right angles to the
direction of energy transfer of the waves. All
electromagnetic waves are transverse waves
Longitudinal waves vibrate parallel to the direction
of energy transfer of the waves. A sound wave is an
example of a longitudinal wave
Mechanical waves, which need a medium
(substance) to travel through, may be
transverse or longitudinal waves
1.5.2 - Measuring waves
- Page 80
For any wave, its amplitude is the
height of the wave crest or the depth of
the wave trough from the position at rest
For any wave, its frequency is the number of
wave crests passing a point in one second
For any wave, its wavelength is the distance
from one wave crest to the next wave crest.
This is the same as the distance from one
wave trough to the next wave trough
v = f x λ
wave speed
= frequency
x
wavelength
1.5.3 - Wave properties: reflection
- Page 82
The normal at a point on a mirror is a
line drawn perpendicular to the mirror
The law of reflection states that: the angle
of incidence = the angle of reflection
For a light ray reflected by a plane mirror:
1 The angle of incidence is the angle
between the incident ray and the normal.
2 The angle of reflection is the angle
between the reflected ray and the normal
1.5.4 - Wave properties: refraction
- Page 84
Refraction is the change of
direction of waves when they
travel across a boundary
When a light ray refracts as it travels from air into glass,
the angle of refraction is less than the angle of incidence
When a light ray refracts as it travels
from glass into air, the angle of refraction
is more than the angle of incidence
1.5.5 - Wave properties: diffraction
- Page 86
Diffraction is the spreading
out of waves when they pass
through a gap or round the
edge of an obstacle
The narrower the gap is,
the greater the diffraction is
If radio waves do not diffract enough when they go
over hills, radio and TV reception will be poor
1.5.6 - Sound
- Page 88
The frequency range of the
normal human ear is from about
20 Hz to about 20,000 Hz
Sound waves are vibrations that travel through a medium
(substance). They cannot travel through a vacuum (as in space)
Echoes are due to sound
waves reflected from a
smooth, hard surface
1.5.7 - Musical sounds
- Page 90
The pitch of a note
increases if the frequency of
the sound waves increases
The loudness of a note increases if the
amplitude of the sound waves increases
Vibrations created in an instrument when it is played produce sound waves
1.2 - Using energy
- Page 44 - 51
1.2.1 - Forms of Energy
- Page 44
Nota:
Sound energy
Infrared energy
Chemical energy
Kinetic energy
Heat energy
Elastic energy
Nuclear energy
Light energy
Electrical energy
Gravitational potential energy
Energy exists in
different forms
Energy can change
from one form to
another
Remember the forms of
energy with the acroynm
SICK HEN LEG
When an object falls and gains
speed, its gravitational potential
energy decreases and its kinetic
energy increases
1.2.2 - Conservation of energy
- Page 46
Energy cannot be created or
destroyed, it can only changes form
The conservation of energy
applies to all energy
changes
1.2.3 - Useful energy
- Page 48
Useful energy is energy in
the place we want it and in
the form we need it
Wasted energy is
energy that is not
useful
Useful energy and wasted energy
both end up being transferred to the
surroundings, which become
warmer
As energy spreads out,
it gets more and more
difficult to use for further
energy transfers
1.2.4 - Energy and efficiency
- Page 50
The efficiency of a device = useful
energy transferred by the device ÷
total energy supplied to the device (x
100%)
No machine can be
more than 100%
efficient
Measures to make machines more efficient include
reducing friction, air resistance, electrical resistance
and noise due to vibrations
1.4 - Generating electricity
- Page 64 - 75
1.4.1 - Fuel for electricity
- Page 64
Electricity generators in power
stations are driven by turbines
Coal, oil and natural gas are burned
in fossil fuel power stations
Uranium or plutoium are used as the fuel in
a nuclear power station. Much more energy
is released per kg from uranium or plutonium
than from fossil fuels
Biofuels are renewable sources of
energy. Biofuels such as methane and
ethanol can be used to generate electricity
1.4.2 - Energy from wind and water
- Page 66
A wind turbine is an
electricity generator on top of
a tall tower
Waves generate electricity by turning a
floating generator
Hydroelectricity generators are turned by
water running downhill
A tidal power
station traps
each high tide
and uses it to
turn generators
1.4.3 - Power from
the Sun and the Earth
- Page 68
Solar cells are flat solid cells that convert solar
energy directly into electricity
Solar heating panels use the
Sun's energy to heat water directly
Geothermal energy
comes from the energy
realeased by radioactive
substances deep inside
the Earth
Water pumped into hot rocks
underground produces steam to
drive turbines that generate
electricity
1.4.4 - Energy and the environment
- Page 70
Fossil fuels produce increased levels of
greenhouse gases which could cause gloabal
warming
Nuclear fuels
produce radioactive
waste
Renewable energy resources can affect plant and
animal life
1.4.5 - The National Grid
- Page 72
The National Grid is a network
of cables and transformers
that distributes electricity to
our homes from distant power
stations and renewable energy
generators
Step-up transformers are used to step up power station voltages to the grid
voltage. Step-down transformers are used to stepd the grid voltage down for
use in homes
A high grid voltage reduces energy loss and
makes the system more efficient
1.4.6 - Big energy issues
- Page 74
Gas-fired power stations and
pumped-storage stations can meet
variations in demand
Nuclear, coal and oil power stations can
meet base-load demand
Nuclear power stations, fossil-fuel power
stations using carbon capture and renewable
energy are all likely to contribute to future
energy supplies
1.3 - Electrical energy
- Page 54 - 61
1.3.1 - Electrical appliances
- Page 54
Electrical appliances can transfer electrical
energy into useful energy at the flick of a switch
Uses of everyday
electrical appliances
include heating, lighting,
making objects move
(using an electric motor),
creating sound and
creating visual images
An electrical appliance is designed for a
particular purpose and should waste as little
energy as possible
1.3.2 - Electrical power
- Page 56
Power is a rate of
transfer of energy
Power = energy transferred ÷ time
In this equation power is in watts (W),
energy transferred is in joules (J) and time
is in seconds (s)
1.3.3 - Using electrical energy
- Page 58
The kilowatt-hour is the
energy supplied to a 1kW
appliance in 1 hour
Total cost = number of
kWh used x cost per
kWh
1.3.4 - Cost effectiveness matters
- Page 60
Cost effectiveness means
getting the best value for
money
To compare the cost effectiveness of different appliances, we need to take account of
costs to buy it, running costs and other costs such as environmental costs
1.6 - Electromagnetic waves -
Page 94 - 103
1.6.1 - The electromagnetic spectrum
- Page 94
The electromagnetic spectrum (in
order of decreasing wavelength,
increasing frequency and energy) is: -
radio waves, - microwaves, - infrared
radiation, - light, - ultraviolet radiation, -
gamma radiation and x-rays
The wave speed equation is used to calculate the
frequency or the wavelength of electromagnetic waves
1.6.2 - Light, infrared, microwaves
and radio waves - Page 96
White light contains all the
colours of the visible spectrum
Infrared radiation is used for carrying signals from
remote handsets and inside optical fibres
We use microwaves to carry satellite TV
programmes and mobile phone calls.
Radio waves are used for
radio and TV broadcasting,
radio communications and
mobile phone calls
Different types of electromagnetic radiation are hazardous
in different ways. Microwaves and radio waves can cause
internal heating. Infrared radiation can cause skin burns
1.6.3 - Communications
- Page 98
Radio waves of different frequencies are used for
different purposes because the wavelength (and
therefore frequency) of waves affects: - how far they
can go, - how much they spread, - how much
information they can carry
Microwaves are used for satellite TV signals
Further research is needed to evaluate
whether or not mobile phones are safe
to use
Optical fibres are very thin transparent
fibres that are used to transmit signals
by light and infrared radiation
1.6.4 - The expanding universe
- Page 100
The doppler effect is the change in observed
wavelength (and frequency) of waves due to
the motion of the source of the waves
The red-shift of a distant galaxy is the shift to
longer wavelengths of the light from it
because the galaxy is moving away from us
The faster a distant
galaxy is moving
away from us, the
greater its red-shift is
All the distant galaxies show
a red-shift. The further away
a distant galaxy is from us,
the greater its red-shift is
The distant galaxies are all moving away from
us because the universe is expanding
1.6.5 - The Big Bang
- Page 102
The universe started with the
Big Bang, a massive explosion
from a very small point
The universe has been expanding
ever since the Big Bang
Cosmic microwave background
radiation (CMBR) is electromagnetic
radiation created just after the Big Bang
CMBR can only be
explained by the Big
Bang theory
1.1 - Energy Transfer by heating
- Page 26 - 41
1.1.1 - Infrared radiation
- Page 24
Infrared radiation is energy transfer by
electromagnetic waves.
All object emit infrared
radiation
The hotter an object is, the more
infrared radiation it emits in a
given time
1.1.2 - Surfaces and radiation
- Page 26
Dark, matt surfaces emit more
radiation than light, shiny surfaces
Dark, matt surfaces absorb more
infrared radiation than light, shiny
surfaces
Light, shiny surfaces reflect more
infrared radiation than dark, matt
surfaces
1.1.3 - States of matter
- Page 28
Flow, shape,
volume and
density are the
properties used
to describe each
state of matter
The particles in
a solid are held
together in fixed
positions
The particles in a
liquid move about
at random and
are in contact
with each other
The particles in a gas move
about randomly and are much
further apart than particles in
a solid or liquid
1.1.4 - Conduction
- Page 30
Metals are the
best conductors of
energy
Materials such as
wood and
fibreglass are the
best insulators
Conduction of energy in a
metal is due mainly to free
electrons transferring energy
inside the metal
Non-metals are poor
conductors because they do
not contain free electrons
1.1.5 - Convection
- Page 32
Convection is the
circlation of a fluid
(liquid or gas) caused
by heating it
Convection takes place
only in liquids and gases
Heating a liquid or a gas
makes it less dense so it
rises and causes circulation
1.1.6 - Evaporation
and condensation -
Page 34
Evaporation
is when a
liquid turns
into a gas
Condensation is
when a gas turns
into a liquid
Cooling by evaporation of a
liquid is due to faster moving
molecules escaping from the
liquid
Evaporation can be increased by increasing the
surface area of the liquid, by increasing the liquid's
temperature, or by creating a draught of air across
the liquid's surface
Condensation on a surface can be
increased by increasing the area of
the surface or reducing the
temperature of the surface
1.1.7 - Energy transfer by design
- Page 36
The rate of energy transferred to or
from an object depends on: - the shape,
size and type of material of the object -
the materials the object is in contact with
- the temperature difference between the
object and its surroundings.
1.1.8 - Specific heat
capacity - Page 38
The greater the mass of an
object, the more slowly its
temperature increases when it is
heated
The rate of temperature change of a
substance when it is heated depends on:
the energy supplied to it, its mass and its
specific heat capacity
Storage heaters use
off-peak electricity to
store energy in
special bricks
1.1.9 - Heating and insulating buildings
- Page 40
Energy transfer from our homes can
be reduced by fitting: loft insulation,
cavity wall insulation, double glazing,
draught proofing and aluminium foil
behind radiators
U-values tell us how much
energy per second passes
through different materials
Solar heating panels do not use
fuel to heat water but they are
expensive to buy and install