CASA B-03a Electrical Fundamentals I PDF

Summary

Aviation Australia's training material "Electrical Fundamentals I" (Module 03), a professional document, covers fundamental concepts in electricity, including knowledge levels, basic theory, and a table of contents.

Full Transcript

MODULE 03

Category B Licence

CASA B-03a

Electrical Fundamentals I

Copyright © 2020 Aviation Australia
All rights reserved. No part of this document may be reproduced, transferred, sold or
otherwise disposed of, without the written permission of Aviation Australia.
CONTROLLED DOCUMENT

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Knowledge Levels
Category A, B1, B2 and C Aircraft Maintenance Licence
Basic knowledge for categories A, B1 and B2 are indicated by the allocation of knowledge levels indicators (1, 2
or 3) against each applicable subject. Category C applicants must meet either the category B1 or the category
B2 basic knowledge levels.
The knowledge level indicators are defined as follows:
LEVEL 1
Objectives:
The applicant should be familiar with the basic elements of the subject.
The applicant should be able to give a simple description of the whole subject, using common
words and examples.
The applicant should be able to use typical terms.
LEVEL 2
A general knowledge of the theoretical and practical aspects of the subject.
An ability to apply that knowledge.
Objectives:
The applicant should be able to understand the theoretical fundamentals of the subject.
The applicant should be able to give a general description of the subject using, as appropriate,
typical examples.
The applicant should be able to use mathematical formulae in conjunction with physical laws
describing the subject.
The applicant should be able to read and understand sketches, drawings and schematics
describing the subject.
The applicant should be able to apply his knowledge in a practical manner using detailed
procedures.
LEVEL 3
A detailed knowledge of the theoretical and practical aspects of the subject.
A capacity to combine and apply the separate elements of knowledge in a logical and comprehensive manner.
Objectives:
The applicant should know the theory of the subject and interrelationships with other subjects.
The applicant should be able to give a detailed description of the subject using theoretical
fundamentals and specific examples.
The applicant should understand and be able to use mathematical formulae related to the subject.
The applicant should be able to read, understand and prepare sketches, simple drawings and
schematics describing the subject.
The applicant should be able to apply his knowledge in a practical manner using manufacturer's
instructions.
The applicant should be able to interpret results from various sources and measurements and
apply corrective action where appropriate.

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Table of Contents
Electron Theory (3.1)
Learning Objectives

12

Electron Theory

13

12

Atoms

13

Electron Shells

14

Energy Levels

15

Electron Flow

16

Energy Bands

18

Ions

19

Molecules

20

Compounds

21

Electrical Properties of Molecules and Compounds

22

Conductors, Insulators and Semiconductors

25

Conductors

25

Insulators

26

Semiconductors
Static Electricity and Conduction (3.2)
Learning Objectives

27
29
29

Static Electricity

30

Static Charge

30

Triboelectric Effect

30

Coulomb’s Law of Charges

33

Distribution of Electrostatic Charges

34

Electrostatic Attraction and Repulsion

34

Dissipation of Accumulated Charges

35

Conduction of Electricity in Materials
Conduction of Electricity in Solids

37

Relative Resistances of Solid Conducting Materials

38

Conduction of Electricity in Liquids

39

Conductivity of Liquids

40

Conduction of Electricity in Gases

41

Thermionic Emission

42

Conduction of Electricity in a Vacuum
Electrical Terminology (3.3)

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Learning Objectives

46

Electrical Terminology

47

Electric Charge

47

Electric Current

47

Electric Current Flow Conventions

48

Electromotive Force/Voltage

49

Potential Difference

49

Resistance

51

Ohm's Law

52

Conductance
Generation of Electricity (3.4)
Learning Objectives

52

Generation of Electricity

54

53
53

Voltage Produced by Friction

54

Voltage Produced by Pressure

56

Voltage Produced by Heat

58

Voltage Produced by Light

59

Voltage Produced by Chemical Action

61

Voltage Produced by Magnetism and Motion
DC Sources of Electricity I (3.5)
Learning Objectives

63

The Cell

68
69

Galvanic Cell

69

Container

69

Electrodes

70

Electrolyte

71

Electrochemical Action

72

Cell Categories

73

Primary Cells

74

Alkaline Cells

75

Secondary Cells

76

Lead-Acid Battery Construction

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68

78

Lead-Acid Battery

78

Battery Construction

78

Lead-Acid Electrolyte

80

Electrochemical Reaction

81

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Lead-Acid Discharging

82

Lead-Acid Charging

83

Service Life Killers

83

Internal Resistance of Electric Cells

84

Nickel-Cadmium Cell

86

Introduction to the Nickel-Cadmium Cell

86

Nickel-Cadmium Cell Thermal Runaway

87

Neutralising Spills

89

Other Types of Secondary Cells
Modern Cells

91
91

Silver-Zinc Cells
DC Sources of Electricity II (3.5)

91
93

Learning Objectives

93

Combining Cells

94

Connecting Cells

94

Battery Voltage

94

Series Connected Cells

95

Series Cell Implementation

96

Parallel Connected Cells

96

Series-Parallel Connected Cells

99

Thermocouples

103

Purpose of Thermocouples

103

Thermocouple Operation

103

Typical Thermocouples

105

Light

107

Electromagnetic Radiation

107

Photoelectric Cell

107

Anatomy of a Solar Cell
DC Circuits (3.6)
Learning Objectives

109
112
112

Voltage, Current and Resistance

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113

Ohm's Law

113

Kirchhoff's Current Law

114

Kirchhoff's Voltage Law

114

Circuit Analysis

116

Series Aiding and Opposing EMF Sources

121

Current Dividers

121
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Voltage Dividers

124

DC Power Supply Internal Resistance
Resistance and Resistor I (3.7)
Learning Objectives
Resistance

125
127
127
128

Resistance

128

Factors Affecting Resistance

128

Specific Resistance/Resistivity

131

Resistor Stability vs Temperature

132

Resistor Labelling

133

Resistor Colour Codes

133

Four-Band Resistor Colour Code

133

Five-Band Resistor Colour Code

134

Resistor Markings

135

Standard EIA Decade Resistor Values Table

136

Wattage Ratings

138

Resistors Connected in Series and Parallel

139

Resistors Connected in Series

139

Resistors Connected in Parallel

139

Series-Parallel Combinations

140

Complex Series-Parallel Combinations
Resistance and Resistor II (3.7)
Learning Objectives
Potentiometers and Rheostats

142
146
146
147

Potentiometer

147

Rheostat

147

Galvanometer

148

Wheatstone Bridges

150

Purpose of the Wheatstone Bridge

150

Wheatstone Bridge Operation

150

Temperature Coefficient

153

Conductance

153

Temperature Effect on Resistance

153

Fixed Resistors

156

Resistors

156

Thermistors and Voltage Dependent Resistors
Thermistors
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Voltage-Dependent Resistor
Power (3.8)
Learning Objectives
Power, Work and Energy

162
164
164
165

Work

165

Energy

165

Kinetic Energy and Potential Energy

166

Work and Power

167

Power

168

Electrical Formulae

170

Power Calculations

171

Capacitance and Capacitors (3.9)
Learning Objectives
Basic Capacitor

174
174
175

Capacitor and Capacitance

175

Capacitor Operation

175

Factors Affecting Capacitance

178

Capacitance Values

178

Physical Properties

178

Area of Plates and Number of Plates

179

Distance Between Plates

179

Dielectric

180

Dielectric Constant

181

Dielectric Strength

181

Working Voltage

182

Construction of Capacitors

184

Common Capacitors

184

Ceramic Capacitors

184

Mica Capacitors

185

Electrolytic Capacitors

186

Tantalum Capacitors

186

Capacitor Colour Coding

188

Variable Capacitors

188

Charging and Discharging of Capacitors

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190

Resistor Capacitor Circuits

190

Exponential Capacitor Charge

190

Time Constant for Exponential Charge

191

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Exponential Capacitor Discharge
Calculating Circuit Capacitance

191
193

Capacitors in Parallel

193

Capacitors in Series

193

Testing Capacitors

195

Visual Inspection

195

Verify the Correct Capacitance

195

Magnetism I (3.10)
Learning Objectives

198
198

Magnetism

199

Magnetism and Electricity

199

Weber’s Theory of Magnetism

199

Domain Theory

201

Magnetic Flux and Flux Density

202

Magnetic Materials

204

Magnetic Poles

208

Earth's Magnetic Poles

208

Law of Magnetic Poles

209

Magnetic Lines of Force

210

General Properties of Magnetic Lines of Force

211

Magnetisation

213

Demagnetisation

215

Magnetic Shielding

217

Magnetic Properties and Materials

220

Reluctance and Permeability

220

Saturation Point

220

Hysteresis

221

Coercivity and Remanence in Permanent Magnets
Magnetism II (3.10)
Learning Objectives
Electromagnetic Fields

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223
226
226
227

Electromagnets

227

Left-Hand Grasp Rule

227

Parallel Conductors

229

Electromagnetic Fields

229

Effect of Multiple Coils

230

Left-Hand Grasp Rule for Polarity

231

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Electromagnetic Field Strength
Magnetomotive Force

232
235

Magnetic Field Strength

235

Field Intensity/Field Strength

236

Magnetic Flux Density

237

Eddy Currents

238

Care of Magnets

239

Magnetic Terminology
DC Motor and Generator Theory (3.12)

240
242

Learning Objectives

242

DC Generator Theory

243

Electromagnetic Induction

243

Left-Hand Rule for Generators

244

Basic AC Generator

245

Generator Principles

250

Elementary DC Generator

251

Typical DC Generator Construction

252

Generator Field Frame

254

Effect of an Additional Armature Coil

255

Electromagnetic Poles

257

Brushes

258

Commutator

259

Commutation

259

Armature

261

Armature Two-Layer Winding

262

Armature Reaction

262

Armature Reaction in Generator With Field Windings

263

Compensating Windings and Interpoles

264

Motor Reaction in a Generator

265

Armature Losses

266

Terminal Voltage

269

Field Excitation

270

Series Wound Generator

272

Shunt Wound Generator

273

Compound Wound Generators

274

DC Motors

276

Inducing a Force on a Conductor
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Principles of Operation

276

Torque

278

Torque in a DC Motor

279

Commutator and Brushes on a DC Motor

280

Counter-EMF

281

DC Motor Types

283

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Motor Types

283

Series Motor

283

Series Motor Speed Control

284

Shunt Motor

285

Compound Motors

288

Separately Excited Motor

290

DC Motor Characteristics

291

Reversing Motor Direction

292

Armature Reaction in DC Motors

293

Cancelling Armature Reaction

294

Starter Generators

295

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Electron Theory (3.1)
Learning Objectives
3.1.1.1 Recall the structure and distribution of electrical charges within atoms (Level 1).
3.1.1.2 Recall the structure and distribution of electrical charges within molecules (Level
1).
3.1.1.3 Recall the structure and distribution of electrical charges within ions (Level 1).
3.1.1.4 Recall the structure and distribution of electrical charges within compounds (Level
1).
3.1.2.1 Define the molecular structure and nature of conductors (Level 1).
3.1.2.2 Define the molecular structure and nature of semiconductors (Level 1).
3.1.2.3 Define the molecular structure and nature of insulators (Level 1).

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Electron Theory
Atoms
All materials are made up of atoms. The atoms contribute to the electrical properties of a material,
including its ability to conduct electrical current.
For the purpose of discussing electrical properties, an atom can be represented by the valence shell
and a core that consists of all the inner shells and the nucleus.
This concept has been demonstrated in the Carbon atom below. The key features are:
The Nucleus (at the centre of the atom) - containing both protons and neutrons.
Electron shells (also referred to as rings) - containing electrons.

© Aviation Australia

Carbon Atom
The charges of these atomic elements are as follows:
Protons – positively charged
Neutrons – neutrally charged
Electrons – negatively charged.

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© Aviation Australia

Atomic structure
All elements follow this foundational structure, containing protons, neutrons and electrons, but not
all elements conduct electricity. Electricity is defined as the flow of electrons between atoms and
therefore a materials conductivity is determined by its willingness to share electrons. A material that
can easily conduct electricity (or share electrons) is known as a conductor. A material that doesn't
conduct electricity is known as an insulator. A third material type, that can range between both a
conductor and an insulator is known as a semiconductor.

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Electron Shells
Electrons occupy electron shells (or orbits), each of which are located at a certain distance from the
nucleus. Each of the electrons in a particular electron shell possess a discrete amount of energy. Some
atoms can have up to seven electron shells. Electrons with the least amount of energy are in the
electron shell closest to the nucleus and electrons that possess the greatest amount of energy are in
the shell furthest from the nucleus.
The electron's that are further away from the nucleus are also held more weakly by the nucleus
forces, and thus can be removed by spending less energy. Hence we say that these electrons are
"loosely bound" to the atom.
The outermost shell of the atom is known as the valence shell and contains the valence
electrons. Each electron shell corresponds to a different energy level and (the first four shells) are
labelled by the letters K, L, M and N.

© Aviation Australia

Electron Orbits

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Energy Levels
Energy levels and electron shells are commonly used interchangeably. Both of these terms
correspond to a fixed distance from the nucleus where the electrons are most likely to be found. The
energy levels increase at each shell outward from the nucleus. Each successive shell can only hold a
certain number of electrons. In the diagram below the electron shell capacities are 2, 8, 18 and 32
respectively (the first shell can hold 2 electrons, the second 8 and so on).
The rules that dictate the total number of electrons in which a shell can hold varies from atom to
atom and requires a deeper understanding of chemistry - beyond that which is required for this
module.

© Aviation Australia

Electron energy levels (first four levels)
In Aviation, electron theory is focused on the atomic valence shell and how it enables conduction and
current flow. A knowledge of the detailed inner workings of an atom and how electrons behave
beyond the valence shell may not be required, however a thorough understanding of certain
materials that conduct and insulate electricity and why they do so is required.
Importantly, the outermost shell of the atom is the valence shell and forms a significant energy band
known as the valence band. This valence band determines whether or not an atoms electrons will
flow (easily).

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Electron Flow
A balanced atom has an equal number of protons and electrons. In the balanced state, an atom will
always have an equal number of protons and electrons, and thus will have a net charge of zero.

Hydrogen (1 Proton and 1 Electron)
All matter contains energy, and the energy in an atom causes the electrons to spin around the
nucleus. As the electrons spin, the centrifugal force tends to pull them away from the nucleus.
However, the electrostatic attraction between the protons and the electrons produces a force which
opposes the centrifugal force and holds the electrons in a specific orbit.
A balanced atom's electrons will remain in their orbits as long as nothing upsets this balance. Positive
electrical forces outside an atom can disrupt the balance and will tend to attract or 'steal' electrons
from the outer ring. This outside electrical force could be caused by effects such as static friction,
passing a wire through a magnetic field or from a chemical reaction (like within a dry cell battery).
Other free electrons move to fill the space vacated by the first free electron. When this conditions
occurs continuously, the movement of electrons becomes an electron flow known as current.

© Aviation Australia

Electron flow
The result of gaining or losing electrons leaves the atom in an unbalanced electrostatic condition with
an electrical charge. Charged atoms are called ions. If an atom has too many electrons, it is a
negatively charged ion, and if it has too few electrons, it is a positively charged ion. The amount of
energy that it takes for an atom to become negatively or positively charged is determined by the
electrons in valence band of an atom.

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All electrons are alike, as are all protons and all neutrons. The structure, number and arrangement of
these subatomic particles is what makes atoms differ from each other. For example, the simplest
atom - a Hydrogen atom, has only one proton and one electron with only one electron shell (shown
above). In contrast, the nucleus of a copper atom has 29 protons with 29 electrons orbiting the
nucleus spread across four shells (shown below).

© Aviation Australia

Copper Atom (29 Protons and 29 Electrons)
Both hydrogen and copper are examples of atoms in a balanced state because they contain exactly
the same number of protons (positive) and electrons (negative). The neutrons have no effect on the
flow of electricity.

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Energy Bands
The valence band of an atom contains the valence electrons. When an electron in the valence band
acquires enough additional energy, it can leave the valence shell and become a free electron. A free
electron exists in what is known as the conduction band.
The difference in energy between the valence band and the conduction band is called an energy gap
(also referred to as band gap). This is the amount of energy that a valence electron must have in order
to jump from the valence band to the conduction band. Once in the conduction band, the electron is
free to move throughout the material and is not tied to any given atom.
The illustration below shows energy diagrams for insulators, semiconductors and conductors.

© Aviation Australia

Energy Bands in the three material types
Insulators have a very large band gap. Valence electrons do not jump into the conduction band except
under breakdown conditions where extremely high voltages are applied across the material.
Semiconductors have a much narrower energy gap. This gap permits some valence electrons to jump
into the conduction band and become free electrons, by adding energy such as heat. By contrast the
energy bands in conductors overlap. In a conductive material there is always a large number of free
electrons.

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Ions
Normal atoms have a neutral charge, that is, they contain the same number of positively charged
protons as negatively charged electrons.
An ion is an atom that has lost or gained electrons. Its charge is positive if the atom has lost electrons
and negative if the atom has gained electrons.

Neutral Atom and both Positive and Negative Ions
For example, Copper (Cu) contains 29 electrons in it's neutral state. It is possible for copper to
become ionised. Two common ions of copper are Copper (1+) and Copper (2+).
Copper (1+) - Copper with one additional positive charge is known as the Cuprous ion (Cu+).
Copper (2+) - Copper with two additional positive charges is known as the Cupric ion (Cu2+).
Any atom which gains or loses electrons becomes an ion, so each element may have variations in both
the positive and negative direction.

Neon Lights
A common practical use of ionisation is in Neon lighting.
The group of elements on the periodic table which are known to be the most stable are called the
noble gases. The noble gases contain the maximum number of valence electrons in their filled valance
shell and are unreactive to other elements (under normal conditions). Neon (Ne) is one of these noble
gases. A neon light is a sealed glass tube filled with neon gas that when ionised by high voltage,
conducts electric current. This conduction can be used to produce light and in the case of Neon,
produce red light. The different noble gases can be used to produce different colours.

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Molecules
A molecule is two or more atoms bonded together and is the smallest particle to which a substance
can be reduced and retain its characteristics. Electrically, a molecules conductivity depends on the
bonded elements. Generally, ionic bonds join metals to nonmetals, covalent bonds join nonmetals to
nonmetals and metallic bonds are responsible for the bonding between metal atoms. The metallic
bonding that occurs between different metals, forms an alloy. Aluminum foil and copper wire are
examples of metallic bonding in action and are known for conducting electricity well.

Molecular Structure (Nicotine - C10H14N2)

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Compounds
A compound is matter in which all the molecules are identical, but the molecules are comprised of
different atoms in exact proportions. Two or more individual elements combine to form a separate
substance whose characteristics may be completely different from the original elements’
characteristics.

Molecule vs Compound
Molecule is the general term used to describe any atoms that are connected by chemical bonds. Every
combination of atoms is a molecule. A compound is a molecule made of atoms from different
elements. All compounds are molecules, but not all molecules are compounds.
Water is a compound because it is made up of hydrogen and oxygen atoms (H2O). Carbon dioxide
(CO2) and common salt, sodium chloride (NaCl), are also compounds.

© Aviation Australia

Water Molecule

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Electrical Properties of Molecules and Compounds
Compounds that conduct a current are held together by electrostatic forces. They contain a
positively charged atom (or molecule), known as a cation, and a negatively charged atom (or
molecule), known as an anion. In their solid state, compounds do not conduct electricity, but when
dissolved in water, the ions dissociate and can conduct a current.
At high temperatures, when these compounds become liquid, the cations and anions begin to flow
and can conduct electricity without water. Non-ionic compounds, or compounds that do not
dissociate into ions, do not conduct a current. You can construct a simple circuit with a light bulb as an
indicator to test the conductivity of aqueous compounds. The test compound in this setup will
complete the circuit and turn on the light bulb if it can conduct a current.
Typically, it is understood that water and electricity do not mix, ever. However, pure water is in fact an
insulator and does not conduct electricity. It is the impurities that are introduced to water which
make it conductive. When salts and other inorganic chemicals dissolve in water, they break into ions.
The water that is seen in nature and the water that we use in our daily life contains several impurities
and charged ions which makes it a very good conductor of electricity.
An electrolyte is defined as any liquid or gel which contains ions and can be decomposed by
electrolysis.

Some compounds may conduct electricity where others may not
To describe the compounds in the diagram (above), ethanol is an alcohol made up of carbon, hydrogen
and oxygen and is an insulator. Potassium chloride (KCl which is also known as potassium salt) when
dissolved in water makes an excellent conductor. And, acetic acid, which is the main component of
vinegar is also a compound of carbon, hydrogen and oxygen and is a poor conductor of electricity.

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Compounds with Strong Conductivity
The easiest way to determine whether a compound can conduct a current is to identify its molecular
structure. Compounds with strong conductivity dissociate completely into charged atoms or
molecules, or ions, when dissolved in water. These ions can move and carry a current effectively. The
higher the concentration of ions, the greater the conductivity. Table salt, or sodium chloride, are
examples of compounds with strong conductivity. It dissociates into positively charged sodium and
negatively charged chlorine ions in water.

Compounds with Weak Conductivity
Compounds that dissociate only partially in water are weak electrolytes and poor conductors of an
electric current. Acetic acid which is the compound present in vinegar, is a weak electrolyte because
it dissociates slowly in water.

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Conductors, Insulators and Semiconductors
Conductors
The most commonly used conductors are single-element materials, such as copper, silver, gold and
aluminium, which are characterised by atoms that have a single valence electron very loosely bound
to the atom. These valence electrons can move freely around the conductor due to the overlap in the
energy level of valence and conduction electrons. A conductive material has many free electrons that,
when moving in the same direction, make up the electric current.

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Good conductors have 1-3 electrons in the outer (valence) shell
The atomic number of the elements have been included in the diagram above. Recall that the atomic
number is the number of protons in the nucleus of an atom. In a neutral or balanced atom the number
of protons always equals the number of electrons. The electron counts for each shell can be identified
with the valence electrons (the furthest right number) in these conductors being between 1 and 3.
Copper (Cu) is the most commonly used conductor due to it's availability and price (in comparison
with silver and gold) and is commonly used as wire in electric circuits.
Copper has only one valence electron. When a positive force is applied, the valence electron is drawn
away, leaving the atom positively charged. The atom now has more protons than electrons, thus
creating a positive ion. The now positive ion tries to attract electrons from surrounding atoms.

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© Aviation Australia

Electron flow in a copper wire

Insulators
An insulator is any material that inhibits (stops) the flow of electrons (electricity). An insulator is any
material with five to eight free electrons in its valence shell.

An insulator has 5-8 electrons in the valence shell
Because electrons in atoms with this number in the valence shell are held (bound) tightly to the atom,
they cannot be easily moved to another atom or make room for more electrons.
Some common insulators are glass, air, plastic, rubber, and wood.

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Rubber (natural rubber), for example, is a hydrocarbon and made up of hydrogen atoms and carbon
atoms. In rubber, the electrons are tightly bound within the material, which means that they are not
free to be shared by neighboring atoms. This is why rubber and it's variants are commonly used as the
insulators around copper wiring.

Semiconductors
A semiconductor is a material which can act as both an insulator and a conductor. The nature of a
semiconductor makes it an extremely useful tool in electronics. Semiconductors are employed in
various kinds of electronic devices, including diodes, transistors, and integrated circuits.
A semiconductor has four electrons in its valence shell. The two most common semiconductor
elements exists in this configuration: silicon (Si) and germanium (Ge). Gallium arsenide (GaAs) is
another common semiconductor material, however unlike silicon and germanium it is compound
rather than an element. Carbon is also a semiconductor, it conducts electricity in some of its forms,
such as graphite, but it doesn't conduct nearly as well as metals like copper or gold. In forms such as
diamond, carbon is an insulator.

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Semiconductor atomic structure (4 electrons in valence shell)
Silicon and germanium have four electrons in their valence shell which allows them to form a
crystalline (crystal) structure. Silicon is abundantly available in quartzite. Extraction, purification, and
crystallization processes for silicon are both efficient and economical. It is what makes silicon the
most common semiconductor element in the world.
The four electrons form perfect covalent bonds (i.e. the attraction/repulsion stability that forms
between atoms when they share electrons) with four neighbouring atoms, creating a lattice.
In carbon, we know the crystalline form as diamond. In silicon, the crystalline form is a silvery,
metallic-looking substance.

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Silicon structure with good semiconductor properties
As electricity involves the flow of electrons, metals tend to be good conductors of electricity because
they have 'free electrons' that can move easily between atoms. While silicon crystals look metallic,
they are not in fact metals. All of the outer electrons in a silicon crystal are involved in perfect
covalent bonds, so they can't move around. A pure silicon crystal is nearly an insulator – very little
electricity will flow through it.
Neither silicon nor germanium will conduct electricity. This is due to the number of electrons in the
valence shell, combined with the strong covalent bonds formed when valence electrons in one atom
mix with those in another. The process that changes the behaviour of silicon or germanium to allow
conduction is known as doping.

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Static Electricity and Conduction (3.2)
Learning Objectives
3.2.1.1 Describe the nature, causes and effects of static electricity (Level 2).
3.2.1.2 Describe the distribution of electrostatic charges in materials, the effect of
electrostatic charge imbalance (Level 2).
3.2.1.3 Describe the methods for dissipation of accumulated static charges in aircraft
(Level 2).
3.2.2 Describe the laws of electrostatic attraction and repulsion (Level 2).
3.2.3.1 Describe the units of electrostatic charge (Level 2).
3.2.3.2 Explain Coulomb's Law (Level 2).
3.2.4.1 Describe how conduction of electricity occurs in solids (Level 2).
3.2.4.2 Describe how conduction of electricity occurs in liquids (Level 2).
3.2.4.3 Describe how conduction of electricity occurs in gases (Level 2).
3.2.4.4 Describe how conduction of electricity occurs in vacuum (Level 2).

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Static Electricity
Static Charge
All matter is made up of atoms, which are themselves made up of charged particles (electrons and
protons). Protons are positively charged, the electrons are negatively charged, and the neutrons are
neutral. Opposite charges attract (positive to negative) and like charges repel (positive to positive or
negative to negative). Most of the time, these charges are balanced within an atom, which makes the
atom neutral.

An atom may be balanced, positively charged or negatively charged
Static electricity is the result of an imbalance between negative and positive charges in a material.
These charges can build up on the surface of an object until they find a way to be released or
discharged. Examples of static discharge include lightning and the shock that is sometimes felt upon
touching another object (like a car door).
The rubbing of certain materials against one another can transfer negative charges, or
electrons. Some materials at an atomic level hold on to their electrons more tightly than others do.
The strength in which matter holds on to it's electrons determines its place in the triboelectric series.
If a material is more apt to give up electrons when in contact with another material, it is more positive
in the triboelectric series. If a material is more apt to 'capture' electrons when in contact with another
material, it is more negative in the triboelectric series.

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Triboelectric Effect
Friction, pressure and separation are the major causes of static electricity. This process is called the
triboelectric effect (tribo means 'rubbing'). It is a type of contact electrification in which certain
materials become electrically charged after coming into contact with another different material, and
are then separated.

The triboelectric effect between two materials
The electrons are transferred from one substance to another following contact, friction and
separation.

Friction is caused by contact and pressure between materials
The magnitude of the static charge is determined by the material composition, the applied forces, the
separation rate and the relative humidity.
Environmental variables like relative humidity influence the level of electrostatic charges. When
humidity is low, higher static charges are generated.
Static becomes more noticeable in the winter months, in dry climates and in air-conditioned
environments. Increasing humidity to 60% limits static build-up because surface moisture on
materials makes a good conductor. Unfortunately, 60% relative humidity is extremely uncomfortable,
can cause equipment problems and can introduce contaminants into your system.

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Means of static
generation

Electrostatic Voltages at 10% to
20% relative humidity

Electrostatic Voltages at 65% to
90% relative humidity

Walking across carpet

35 000

1 500

Walking over vinyl floor

12 000

250

Worker at a bench

6 000

100

Vinyl envelopes for work
instructions

7 000

600

Plastic bag picked up
from bench

20 000

1 200

Chair padded with
polyurethane foam

18 000

1 500

Triboelectric Series

Triboelectric series positive and negative static generation

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The triboelectric series is a list that ranks materials according to their tendency to gain or lose
electrons. Materials higher on the triboelectric series become positively charged (lose electrons),
those lower in the series become negatively charged (gain electrons) and the elements in the centre
are neutral. The voltage levels generated when two materials are rubbed together can be predicted
as those materials close together in the series will produce less voltage than those further apart in
the series.

Coulomb’s Law of Charges
The relationship between attracting or repelling charged bodies was first discovered and written
about in the 1780s by a French scientist named Charles A. Coulomb.
Coulomb's Law
Charged bodies attract or repel each other with a force that is directly proportional to the product
of their individual charges, and is inversely proportional to the square of the distance between
them.

The amount of attracting or repelling force which acts between two electrically charged bodies in
free space depends on two things:
1. Their charges, and
2. The distance between them.
The strength of attracting and repelling forces varies inversely with the square of the distance
between the two charges. For example, if the distance between two objects with dissimilar charges is
doubled, the force of attraction is reduced to one fourth of its original value. If the distance between
the two objects is tripled, the force of attraction becomes one ninth of its original value. On the other
hand, if the distance between the objects is halved, the force of attraction increases fourfold.
The interaction between charged objects is a non-contact force which acts over some distance of
separation. There are always two charges and a distance between them as the three critical variables
which influence the strength of the interaction.

Aviation Australia

Interaction of two charged particles
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Coulomb's Law Equation
F = ke

q1q2
2

s

Where Ke is the Coulomb constant, q1 and q2 are the signed magnitudes of the charges, and s is the
distance between the charges.
The unit for quantities of electric charge is the Coulomb.
Symbol for coulombs is C.
Symbol for charge is Q.
1 coulomb = 6.25 x 1018 electrons.
In electricity, the practical unit of electrical charge is the coulomb, which is equal to the electric
charge of approximately 6.25 × 1018 electrons. The coulomb measures the quantity of electric
charge, or the number of electrons, regardless of whether the charge is moving or not.

Distribution of Electrostatic Charges
Materials that bear imbalances of opposite charge will attract each other and cling together.
Materials that bear imbalances of like charge will repel each other. When an object bearing an
enormous accumulation of positive or negative charge comes close to another object bearing the
opposite charge, a spark may jump across the space between them. This can result in both the
enormously powerful discharges of lightning and the small yet stimulating shocks we receive when
touching something after shuffling across a carpet in our stocking feet.
Because wool cloth is a material that readily gives up electrons, it is used in many activities to
produce an accumulation of negative charge on an otherwise neutral object. Human hair is another
common material that readily gives up electrons.

Materials of opposite charge will attract each other

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Electrostatic Attraction and Repulsion
An uncharged pith (painted styrofoam) ball is attracted to a rod which is positively or negatively
charged. Regardless of the polarity of the charged rod, because the pith ball is neutral, it will always
react as an opposite polarity. For example, if the rod has lost electrons and is positive, the neutral pith
ball will be of negative polarity with respect to the rod. So the rod being positive and the ball being
negative (with respect to the rod) will cause the ball to be attracted. The attraction will still occur if
the rod has an excess of electrons and is negatively charged. In this case, the ball will appear to be
positively charged with respect to the rod, so it will again be attracted.
Once the rod touches the ball, electrons flow to establish an even balance, and when both the rod and
the pith ball exhibit like electrostatic charges, they repel each other.
A material such as rubber is known as an electrical insulator. Accumulations of charge will not move
across the surface of a rubber object easily. When one part of a balloon is rubbed with wool, the wool
gives up electrons, making that part of the balloon negatively charged even though the rest of the
balloon may remain neutrally charged.
When a charged object, such as a balloon that has been rubbed with wool, is brought near a neutrally
charged object, such as a piece of Styrofoam, the Styrofoam is said to become positively charged by
induction and may leap towards the charged balloon. An object charged by induction does not
actually have to lose or gain electrons. A negatively charged balloon brought near a neutrally charged
piece of Styrofoam repels the electrons on the surface of the Styrofoam. The repelled electrons
migrate as far away from the balloon as possible. This leaves the near end of the Styrofoam with an
imbalance of positive charge and results in the attraction of the Styrofoam to the balloon.

Attraction of opposite and repulsion of like charges

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Dissipation of Accumulated Charges
The feature of charge accumulation at points is used to advantage on some aircraft. Unwanted charge
that dissipates during flight is dissipated into the atmosphere by discharge wicks. These are located
where the air friction can pick off the charge concentrated on them. They are designed, and their
location on the aircraft is selected, to minimise the interference with aircraft radio performance that
may otherwise be caused by uncontrolled random discharges.

Distribution of static charges on different materials and shapes
Discharge wicks are usually fitted to large aircraft, but seldom to small ones. This is because less
charge accumulates on smaller aircraft.

Static discharge wicks on the trailing edges of an aircraft wing

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Conduction of Electricity in Materials
Conduction of Electricity in Solids
In solid conductors made of various metals – silver being the best, closely followed by gold, aluminium
and copper – these materials have a large number of free electrons readily available to move from
atom to atom.
When an electrical force (EMF) is applied to the metal, it attracts these free electrons from their
outer orbits and starts a domino effect with electrons jumping from atom to atom. The result is that
the electricity reaches the other end of the conductor at the speed of light even though the individual
electrons move between atoms. This is called conduction current.

Solid conductor electron flow
An electron leaves the negative terminal of the battery and knocks another electron out of an atom in
the conductor. This free electron in turn knocks an electron out of another atom and takes its place.
At the other end of the conductor cable the negatively charged electrons in the conductor are
attracted to the positive battery terminal.
Electricity is conducted through solids via movement of electrons.
Copper is the material most commonly used as a conductor. Brass, aluminium and carbon are also
used often, and although silver and gold are better conductors than these, they are used only in
special applications because of their high cost. The descending order of conductivity is silver, copper,
gold, aluminium, brass and then carbon.

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© Aviation Australia

Copper wire is the most common conductor used in electrical cable
Although most metals do not conduct electricity as effectively as the above-mentioned metals, all
metals are reasonably good conductors. Many are rarely produced specifically as conductors, but
when they are part of the assemblies manufactured for some other primary purpose, they may also
be used as conductors. Examples of this are the use of steel, aluminium and other metals in aircraft
and automobile structures and engines as conducting mediums, particularly as an earth or return
path.

Electron flow (animated)

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Relative Resistances of Solid Conducting Materials
In practice it is more usual to think of conductors’ and components’ resistance (commonly referred to
as resistivity) rather than their conductance. Copper, with a datum of 1, is used as a baseline by which
to compare other materials’ resistance.

Adapted from Brandes, E. A., Ed., Smithells Metals Reference Book, Sixth Edition, Butterworth Inc. 1983

Electrical resistivity of copper and other pure Metals at 20 degrees
Celcius
Carbon is the only non-metal solid that has significance as a conductor. Although carbon has a
resistance 2000–3000 times that of copper, its self-lubricating quality makes it the most suitable
material for a rubbing connection with commutators or slip rings (which are usually manufactured
from copper) used in generators and alternators.

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Conduction of Electricity in Liquids
When current is passed through some liquids, it creates what we call ions, atoms of liquid or gas that
have either gained or lost an electron. If an atom gains an electron, it has an overall negative charge
(more electrons than protons) and is called a negative ion. If it loses an electron, it has an overall
positive charge (fewer electrons than protons) and is called a positive ion.

Ions - atoms of liquid or gas that have either gained or lost an
electron
In a liquid, it is not so much atoms which are ionised, but rather groups of atoms called molecules.
Negatively charged ions move in one direction and positively charged ions move the opposite way.
The charges they carry are given up at the appropriate electrodes. Usually when this process occurs,
the liquid will be caused to break down into its component parts or, in some cases, one of the metal
electrodes will be eaten away.
Ionic substances are made of charged particles – ions. When the ionic solid is dissolved in water, the
ionic lattice breaks up and the ions become free to move around in the water. When electricity is
passed through the ionic solution, the ions are able to carry the electric current because of their
ability to move freely. A solution conducts by means of freely moving ions.

Conductivity of Liquids
Liquids which are able to conduct ionically are known as electrolytes. It is the chemical nature of
these liquids to form positive and negative ions. Most electrolytes are acid, alkali or salt solutions.

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Solution

Conductivity

Pure water (distilled)

non

Tap water

poor

Pool or sea water

weak

Soluble salt solution (NaCl)

strong

Strong acids

strong

Weak acids

weak

Strong bases

strong

Weak bases (Ammonia)

weak

Molecular compounds (sugar solution)

non

If positive and negative electrodes are placed in an electrolyte, the positive and negative ions will
naturally be attracted to the opposite-polarity electrodes. The ionic transfer of electric charge is a
conduction of current. When ions reach the electrodes, depending on their polarity, they either give
or receive electrons, thus contributing to the electron transfer of charge through the solid conducting
circuit external to the electrolyte.

Electrodes in an electrolyte solution of molten lead bromide
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Conduction of Electricity in Gases
In their normal state gases are insulators, but when ionised they become conductors.
Heat or high electrical potentials can dislodge electrons from, or cause electrons to move into, the
atoms or molecules of a gas. Ions are thus formed and the gas is said to be ionised; in this condition,
the resistance of the gas is markedly decreased.
Ionisation occurs across the gap of spark plugs in piston engines, in fluorescent and gas discharge
lamps, and in the air path of a lightning discharge.

© Aviation Australia

Ionisation in the spark of an engine spark plug

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Thermionic Emission
Thomas Edison discovered the principle of thermionic emission as he looked for ways to keep soot
from clouding his incandescent light bulb. Edison placed a metal plate inside his bulb along with the
normal filament. He left a gap, a space, between the filament and the plate. He then placed a battery
in series between the plate and the filament, with the positive side towards the plate and the negative
side towards the filament.
When Edison connected the filament battery and allowed the filament to heat until it glowed, he
discovered that the ammeter in the filament-plate circuit had deflected and remained deflected. He
reasoned that an electrical current must be flowing in the circuit – even across the gap between the
filament and plate.
Edison could not explain exactly what was happening. At that time, he probably knew less about what
makes up an electric circuit than you do now. Because it did not eliminate the soot problem, he did
little with this discovery. However, he patented the incandescent light bulb and made it available to
the scientific community.

Thermionic emission or The Edison Effect
Let's analyse the circuit. You probably already have a good idea of how Edison’s circuit works. The
heated filament causes electrons to boil from its surface. The battery in the filament-plate circuit
places a positive charge on the plate (because the plate is connected to the positive side of the
battery).
The electrons (negative charge) that boil from the filament are attracted to the positively charged
plate. They continue through the ammeter and battery, and then back to the filament. You can see
that electron flow across the space between filament and plate is actually an application of a basic
law you already know: unlike charges attract.

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Edison's bulb had a vacuum so the filament would glow without burning. Also, the space between the
filament and plate was relatively small. The electrons emitted from the filament did not have far to go
to reach the plate. Thus, the positive charge on the plate was able to attract the negative electrons.

© Aviation Australia

Thermionic emission in the light bulb
The key to this explanation is that the electrons were floating free of the hot filament. It probably
would have taken hundreds of volts to move electrons across the space if they had to be forcibly
pulled from a cold filament. Such an action would destroy the filament and the flow would cease.
Edison’s application of thermionic emission in causing electrons to flow across the space between the
filament and the plate has become known as the Edison effect.
Metallic conductors contain many free electrons, which at any given instant are not bound to atoms.
These free electrons are in continuous motion. The higher the temperature of the conductor, the
more agitated the free electrons, and the faster they move. A temperature can be reached at which
some of the free electrons become so agitated that they actually escape from the conductor. They
'boil' from the conductor's surface. The process is similar to steam leaving the surface of boiling
water.
Heating a conductor to a temperature sufficiently high that it causes the conductor to give off
electrons is called thermionic emission.

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Conduction of Electricity in a Vacuum
Conduction of current in a vacuum is much more difficult to achieve because there are no gas
molecules which can liberate free electrons. It requires a cathode (negative electrode) to be forced to
release electrons either by heating it up (thermionic emission) or by using a high voltage to strip
electrons out of it, as in a thermionic valve (radio valve) or cathode ray tube of the television or
oscilloscope type.
This stream of electrons will then pass across the tube to the anode, which has a high positive
potential (25 000 volts is not uncommon in TV sets).
Electrons are emitted from a cathode by thermionic emission (heating of conductor) and stream
across to the plate (anode) because of electrostatic attraction.

© Aviation Australia

Conduction of electricity in a vacuum

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Electrical Terminology (3.3)
Learning Objectives
3.3.1 Describe potential difference and the factors affecting it (Level 2).
3.3.2 Describe electromotive force and the factors affecting it (Level 2).
3.3.3 Identify the units of voltage and the factors affecting it (Level 2).
3.3.4 Identify the units of current and the factors affecting it (Level 2).
3.3.5 Identify the units of resistance and the factors affecting it (Level 2).
3.3.6 Identify the units of conductance and the factors affecting it (Level 2).
3.3.7 Identify the units of electric charge and the factors affecting it (Level 2).
3.3.8 Describe conventional current flow and the factors affecting it (Level 2).
3.3.9 Describe electron flow and the factors affecting it (Level 2).

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Electrical Terminology
Electric Charge
The coulomb is the unit for quantities of electric charge transferred between points of different
electrical potential.

© Aviation Australia

Coulombs
The coulomb is the electric charge equivalent to a definite number of electrons (6.24 × 1018). The
symbol for coulombs is C. Q (or lowercase q) is used as the symbol for charge.
Q = 3 C or q = 3 C

Q = 3C means a charge of three coulombs.

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Electric Current
Charge may be transferred between points of different potential at varying rates of flow.
The rate of transfer is measured in coulombs per second, and 1 C/s is one ampere.
The ampere is the unit of current.
If 1 C flows through a circuit each second, the current is one ampere; 10 C/s is 10 amperes.
Amp is the abbreviation for ampere. The symbol for amperes is A and I is the symbol for current.
I = 3 A or i = 3 A

I = 3 A means a current of three amps.

Electric Current Flow Conventions
According to the electron theory, the current always flows from the most negative point to the most
positive point. Therefore, if a conductor is connected between the terminals of a power source, that
is, a battery or generator, a current will flow from the negative terminal (-) to the positive terminal (+).
Before scientists understood the true nature of the structure of the atom, electricity had already
been in use for a long time even though no-one knew how or why it worked. It was assumed that, like
water, charges of some type moved from a point of high pressure (+) to a point of low pressure (-). If
the pressure difference was great, then the flow was great, and if the difference was small, so was the
flow.
This is known as the conventional current flow theory and is still in use in some textbooks even today.

© Aviation Australia

Electron flow vs conventional current

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For all your studies of electricity in this course, the electron theory (electron flow) and all the rules
which have been devised for it will be used. Current flow, which is electron movement, is understood
to occur from negative to positive.

Electromotive Force/Voltage
Voltage is a measure of the force or pressure that is applied to electrons to remove them from their
orbits and propel them along a wire.

Electric circuit
It is usually called electromotive force, or EMF for short, so the statement that 12 volts are being
applied to a circuit indicates the EMF being applied to move electrons down the wire.
Current does work or expends energy when it overcomes resistance. As in all cases in which work is
done, a force must perform the work. This force is EMF. The unit for this force is expressed in volts.
The current in a circuit is proportional to the voltage driving it through the circuit. Doubling the
voltage doubles the current, and halving the voltage halves the current.
The symbol for volts is V.
E is the symbol for EMF.
E = 3 V means an electromotive force of 3 volts.

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Potential Difference
Potential is denoted with reference to a point (e.g. +100 V with reference to 0 V).
If we have two bodies, each at a different potential, then the voltage which is measurable between
them is a measure of that difference in potential. It can have either a positive or negative sign,
depending on the point of reference.
Voltage can relate to different points of reference and so have a positive or negative sign. Even if one
of the bodies has a zero charge, the other body can still relate to it as a positive or negative potential.

Potential difference between three independent bodies
The voltage difference between two bodies is called the potential difference (PD) and is measured in
volts.

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Aviation Australia

EMF in a simple circuit

Resistance
The current in a circuit is inversely proportional to the resistance of the circuit. For circuits with a
steady EMF, doubling the resistance halves the current, and halving the resistance doubles the
current.

Resistance is a property that opposes current flow
Resistance is directly proportional to the length of any conductor and inversely proportional to its
cross-sectional area. Thus a 10-m length of copper wire has twice the resistance of a 5-m length of
the same wire. If one copper wire has twice the cross-sectional area of the other, but the same length,
the resistance will be half.
The ohm is the unit of electrical resistance. The symbol for ohms is Ω.

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R is the symbol for resistance.
R = 3 Ω means a resistance of three ohms.

Factors Controlling Resistance
Even the very best conductors have some resistance, which limits the flow of electric current through
them.
The resistance of any object, such as a wire conductor, depends on four factors:
The material of which it is made
Its length
Its cross-sectional area
Its temperature.
For most materials, the hotter the material, the more resistance it offers to the flow of an electric
current. Conversely, the colder the material, the less resistance it offers to the flow of an electric
current.

Ohm's Law
The relationship between voltage, current and resistance can be described by Ohm's law.
V = IR

Conductance
Conductance is the reciprocal of resistance. It is a rarely used term.
The siemen is a unit for the measurement of a material’s ability to conduct current.
1
siemens

G =
R

The symbol for siemens is S. The symbol for conductance is G.
G = 3 S means a conductance of 3 siemens.

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Generation of Electricity (3.4)
Learning Objectives
3.4.1 Describe typical methods by which electricity is generated using light (Level 1).
3.4.2 Describe typical methods by which elec