Electricity Lecture Notes PDF

Summary

These lecture notes cover fundamental concepts of electricity. It explains the basics of static and current electricity, including the difference between insulators and conductors. The notes proceed to discuss the concept of electric charges and forces. It elaborates on Coulomb's Law, including examples and numerical problems.

Full Transcript

Electricity
What is electricity?
The collection or flow of
electrons in the form of
an electric charge
 What is the difference between static
electricity and current electricity?

Static electricity is stationary or collects on
the surface of an object, whereas current
electricity is flowing very rapidly through a
conductor.
What Is Static Electricity?
 A stationary electrical
charge that is built up on
the surface of a material
 Where do charges come from?

Matter is made up of atoms.

+ Proton (positive charge)
–
neutron (neutral)
+
+ +

– electron (negative charge)
– –

atom nucleus
 Where do charges come from?

If electrons = protons neutral

If electrons > protons  gaining electrons, negative
charge
If electrons < protons  losing electrons, positive charge
 Insulators and conductors

Insulators: materials that do NOT
allow electrons to flow through them
easily.

Insulators can be easily charged by friction as the extra
electrons gained CANNOT easily escape.
 4 Insulators and conductors

Conductors: materials that allow electrons to flow
through them easily.

Conductors CANNOT be easily charged by friction as
the extra electrons gained can easily escape.
Electrostatic Force
 Law of Charges

Like charges repel and opposite charges attract

+ +
- -
+ -

 Note that electricity is different from gravitation, in
which the force is always attractive

m1 m2

February 27, 2020 23
 The Unit of Charge

 The unit of charge is the coulomb, abbreviated C

 The coulomb is defined in terms of the SI unit for
electric current, the ampere, abbreviated A

 The ampere is a basic SI unit like the meter, the
second, and the kilogram.

 The unit of charge is defined as
1 C=1As

February 27, 2020 24
 Charge of an Electron
 We can define the unit of charge in terms of the
charge of one electron
An electron is an elementary particle with charge
q = -e where
e = 1.602 · 10-19 C
A proton is a particle with q = +e

e = 1.602 · 10-19 C

February 27, 2020 25
 Coulomb of Charge
 A full coulomb is a very large amount of charge!

 The number of electrons required to produce 1 coulomb
of charge is 1C
Ne   6.24 1018
1.602 10 -19 C
 Because a coulomb is a large amount of charge, everyday
examples of static electricity typically involve
1 micro coulomb = 1 C = 10-6 C
1 nano coulomb = 1 nC = 10-9 C
1 pico coulomb = 1 pC = 10-12 C

February 27, 2020 26
 Insulators and Conductors
 The electronic structure of materials determines their
ability to conduct electricity
“Conducting electricity” means the transport of electrons
 Materials that conduct electricity well are called
conductors
Electrons can move freely (i.e., some of the electrons)
Metals
Water with dissolved materials
 Materials that conduct electricity poorly are called
insulators
Electrons cannot move freely
Glass
Pure water

February 27, 2020 27
 Semiconductors
 Semiconductors are materials that can be switched
between being an insulator and being a conductor.
 Semiconductors are the backbone of modern
electronics and computers.

Replica of first transitor Modern computer chip with
in 1947 millions of transitors

February 27, 2020 28
 Electric Force - Coulomb’s Law
 Consider two electric charges: q1 and q2
 The electric force F between these two
charges separated by a distance r is
given by Coulomb’s Law kq1q2
F 2
r

 The constant k is called Coulomb’s
constant and is given by

k  8.99 10 Nm /C
9 2 2

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 Coulomb’s Law (2)
 The coulomb constant is also written as
1 C2
k where  0  8.85 10 12
4  0 Nm 2

 0 is the
“electric permittivity of vacuum”
A fundamental constant of nature
1q1q 2
F
4 0 r 2

February 27, 2020 34
 Example: Force between Two Charges
 What is the force between two 1 C charges 1 meter
apart?
1
q1q 2
F
4 0 r 2

 9 N  m  1 C 1 C
2
F   8.99 10 
 1 m 
2 2
 C
 8.99 109 N

which is the weight of 450 Space Shuttles at launch

February 27, 2020 35
 Electric Force
 The electric force is given by
q1q2
 The electric force, unlike the
gravitational force, can be positive
Fk 2
or negative r
If the charges have opposite
signs, the force is negative + -
Attractive
If the charges have the same
sign, the force is positive + +
Repulsive - -

February 27, 2020 36
Two equally charges (q2&q1( )0.8x10-9C ) one +ve and
one –ve separated by r= 0.1m ‫المؤثرة على‬calculate electric
force on third charge
qo= 0.4x10-9C )if it puted at a&b. as shown
q2 aq q1
At point a - +3 0.04m
+
0.06m
r=0.1m

r=0.1m r=0.1m b
At point b - + +
q2 F2 q1 F1 q3
calculate electric force affected on q2 due to
‫؟‬q1 and q3 as shown in figure.

- q =1.2ϻc
3

F2
5cm F1

+ q =2.5ϻc
2
- q =3.6ϻc
1

5cm
find electric force on q3 due to q1 and 3‫مثال‬
q2 as shown below