2024S1 PH1012 Physics A - Electromagnetism and Circuits - Electric Fields PDF

Summary

These are lecture notes for a Physics A course on electromagnetism and circuits, focusing on electric fields. The notes cover topics such as electric fields and potentials, Gauss's law, electric potential, and capacitance.

Full Transcript

2024S1 PH1012: Physics A
Electromagnetism and Circuits
Electric Fields

Dr Ho Shen Yong
Lecturer, School of Physical and Mathematical Sciences
Nanyang Technological University

Week 8

"You can't depend on your judgment when your imagination is out of focus."
- Mark Twain

Itinerary
1. Electric fields and potentials
(for point charges and parallel plates).
2. Electric fields, potentials, Gauss’s law
3. Electric potential and capacitance
4. Capacitors in circuits.
5. Electric fields in circuits; resistors and D.C circuits;
6. Kirchhoff's laws; RC circuits. 6. Magnetic Fields and Forces
7. Sources of Magnetic Fields
8. Electromagnetic Induction
Self-check – after completing the lessons (lecture and
tutorial) for this topic, are you able to

1. cite examples of electrostatics and the effects of
charge transfer
2. state Coulomb’s law of electric forces and apply it
solve problems in Physics
3. calculate the net force / field acting on a charge
placed in a system of fixed charges or an external
electric field
4. calculate electric field in problems and demonstrate
understanding of the concept of electric force, field
and flux; the relationship electric potential energy
and electric firce
5. apply Gauss’s law to analyze the relationship between
charge and electric fields
6. calculate electric potential, electric potential energy 1
and solve problems using energy conservation
 Introduction

In mechanics (dynamics), calculations often involve the physical property - mass
of objects. In electricity and magnetism, the key physical property of objects that
is of interest is electric charge. The subject of electricity and magnetism can be
divided into three realms:
1) the charges that we study are at rest with respect to each other and to
observers like us;
2) the charges are moving with a relatively constant average speed in the
circuitry – “electricity”. Another phenomena that involves charges moving at
constant velocity is the generation of magnetic fields.
3) the charges are accelerating – fields can be generated and energy radiated
into space.
Gravitational force is important on scale of planets and our everyday life.
However, electromagnetic interaction is the dominant force at the microscopic
level down to the atomic scale. It is the force responsible for holding the electrons
and the nuclei together in atoms and all forms of molecular bonding – thus
responsible for all of chemical and biological phenomena. Looking at our present
reliance on electrical appliances, we can also safely say that the understanding and
application of electricity and magnetism is one of the cornerstone in the
modernization of human civilization. [email protected]

The unit of charge: Coulomb (C)

The SI unit of charge is Coulomb (C) which is defined as the amount of charge that
flows in 1 second when there is a steady current of 1 ampere. The electron is an
elementary charge carrier and has a charge of −𝑒 where

𝑒 = 1.60217733 × 10−19 𝐶.

The charge of a proton is +𝑒. Thus, we see that one C is made up of many
elementary charges.

Giancoli pg 561 Fig 21.3:
Simple model of atom

2
 Examples of Daily Occurrences and Applications

1. Lightning
2. Electrical igniters at gas stove
3. Charging of cellphones, camera, flash etc
4. Computer Keyboards
5. Capacitive Touchscreens
Aspects of Electrostatics

https://www.youtube.com/ https://www.youtube.com/w
watch?v=dwJ- atch?v=ViZNgU-Yt-Y&t=115s
MM7yu4E&t=3s

3
 Visualizing Charges (Knight)

Pause to Ponder: A rod attracts a positively charged hanging ball.
The rod is
A. Positive.
B. Negative.
C. Neutral.
D. Either A or C.
E. Either B or C.

4
 Charge Polarization (Knight)

Charge polarization is the slight separation of the positive and negative charges in
a neutral object when a charged object is brought near.

The polarization force arises because the charges in a neutral object are slightly
separated, not because the objects are oppositely charged.
The polarization force between a charged object and a neutral one is always
attractive.

5
Pause to Ponder: Metal spheres 1 and 2 are touching. Both are initially
neutral.
a. The charged rod is brought near.
b. The charged rod is then removed.
c. The spheres are separated.
Afterward, the charges on the sphere are:
A. Q1 is + and Q2 is +
B. Q1 is + and Q2 is –
C. Q1 is – and Q2 is +
D. Q1 is – and Q2 is –
E. Q1 is 0 and Q2 is 0

Pause to Ponder: Metal spheres 1 and 2 are touching. Both are initially
neutral.
a. The charged rod is brought near.
b. The spheres are separated.
c. The charged rod is then removed.
Afterward, the charges on the sphere are:
A. Q1 is + and Q2 is +
B. Q1 is + and Q2 is –
C. Q1 is – and Q2 is +
D. Q1 is – and Q2 is –
E. Q1 is 0 and Q2 is 0

6
Atomic view of charging (Knight)

Molecular ions can be created
when one of the bonds in a
large molecule is broken.

7
 Wimshurst Machine and Van der Graff generator

https://commons.wikimedia.org/wiki/File:Wimshurst.jpg
Hand-Cranked Laser –
How it works: See Youtube TEA Laser Powered by Wimshurst Machine
MIT Physics Demo –
The Wimshurst Machine

8
https://en.wikipedia.org/wiki/Van_de_Graaff_generator
 Newton’s Law of Gravitation and Coulomb’s Law

Newton’s Law of Gravitation

Coulomb’s Law on Electrostatic forces

Coulomb’s Law:

Gauss’s Law which was discussed for gravitational fields is also similarly
applicable to electric fields.

9
 Coulomb's law (discovered in 1785)

The magnitude of the force (F) between two electrically charged bodies,
which are small compared with their separation (r), is inversely proportional
to r2 and proportional to the product of their charges (Q1 and Q2):

𝑄𝑄
𝐹 = 𝑘 122
𝑟
where the constant of proportionality k, in vacuum, expressed in SI units is
given by
1
𝑘=
4𝜋𝜀
where 𝜖 is the permittivity. It is dependent on the medium in which the
charges are in. For example, the permittivity of water at room temperature
is about 80 times the permittivity of free space (vacuum) and thus the
attractive forces between Na+ and Cl- is much weaker in water. The
permittivity of free space (vacuum)
−12
𝐶2
𝜀𝑜 = 8.85418781762 × 10.
𝑁 ∙ 𝑚2
For the purpose of simple computation in vacuum, we just use
1
𝑘= = 8.99 × 109 𝑁 ∙ 𝑚2/𝐶2
4𝜋𝜀𝑜

Thus, Coulomb’s law can be written as
𝑄𝑄
𝐹 = 1 2 2.
4𝜋𝜀𝑜𝑟

Taken from Knight, pg 801, Fig 26.17

10
 Comparison with Gravitational force [Serway Ex. 23.1, pg 663]

The electron and proton of a hydrogen atom are separated (on average) by a
distance of approximately 5.3 × 10−11 𝑚. Compare the magnitudes of the
electric force and gravitational force between the two particles.

𝑒 |−𝑒| (1.60×10−19 )2
𝐹𝑒 = 𝑘 = 8.99 × 109 = 8.2 × 10−8 𝑁.
𝑟2 5.3×10−11 2

𝑚𝑒𝑚𝑝 (9.11×10−31 )(1.67×10−27 )
𝐹𝑔 = 𝐺 = 6.67 × 10−11 = 3.6 × 10−47 𝑁.
𝑟 2
5.3×10−11 2

𝐹𝑒Τ ≈ 2 × 1039. Thus, the gravitational attraction is negligible when
𝐹𝑔
considering electric forces.

Example Giancoli page 565, Conceptual Example 21-1: (modified)
Which charge exerts the greater force?
Two positive point charges, Q1 = 50 μC and Q2 = 1 μC, are separated by a
distance 𝑙 = 0.50 m. Calculate the force that Q1 exerts on Q2. What about
the force that Q2 exerts on Q1, will it be larger?.

Point Charges 11
 Giancoli pg 566 Example 21-2: Three charges in a line

Three charged particles are arranged in a line, as shown. Calculate the net
electrostatic force on particle 3 (the -4.0 μC on the right) due to the other two
charges.

𝐹Ԧ32 =

𝐹Ԧ31 =

𝐹Ԧ =

12
Point Charges
 Giancoli pg 566 Example 21-3: Electric force using vector components.

Calculate the net electrostatic force on charge 𝑄3 shown in the figure due to
the charges 𝑄1 and 𝑄2.

|𝐹Ԧ32 | =

|𝐹Ԧ31 | =

𝐹𝑥 =

𝐹𝑦 =

Ԧ =
|𝐹| 𝜃=

Point Charges 13
 Electric field of a point charge

The electric field exist in the region of space around a charged object, the
source charge Q. To study the properties of the electric field, a very small
positive test charge qo is placed in this region to probe the electric field
without distorting it. The test charge qo will experience a force 𝐹റ 𝑒 due to the
source charge. The electric field 𝐸 of the charge Q at a point is defined as
𝐹റ 𝑒
𝐸 ≡ lim
𝑞𝑜→0 𝑞𝑜
Remarks:
General

1. 𝐸 has SI units N/C.
2. The direction of 𝐸 is the direction of force the positive test charge
experiences.
3. The electric field is a property of the charge Q, independent of the test
charge.
4. We can write the force 𝐹റ 𝑒 acting on any charge q in an electric field 𝐸 as
𝐹റ 𝑒 = 𝑞𝐸.
This is true for any electric field.
5. For a point charge Q,
𝐹റ 𝑒 𝑄
𝐸= = 𝑟Ƹ
𝑞𝑜 4𝜋𝜀𝑜𝑟2 [email protected]

The electric field can be represented by field lines. These lines start on a
positive charge and end on a negative charge.

Point Charges 14
Giancoli page 569, Example 21-6: Electric field of a single point charge.
Calculate the magnitude and direction of the electric field at a point P which is
30 cm to the right of a point charge Q = -3.0 x 10-6 C.

What will be the electric field strength at another point
a) 15 cm away from Q (+ve)?

b) 60 cm away from Q (+ve)?

Point Charges

Resultant electric fields of multiple charges in general General
To find 𝐸 for a group of N point charges, the procedure is as follows:
1) Calculate 𝐸 𝑖 due to charge i at the given point as if it were the only
charge present.

2) Add these separately calculated fields vectorially to find the resultant
field 𝐸 at the point. In equation form,
𝐸 = 𝐸1 + 𝐸2 + 𝐸3 + ⋯

3) The equation is an example of the application of superposition.
However, this approach may fail when the magnitudes of the fields are
extremely large (perhaps causing polarization of non-elementary source
charges) but in the present course, it is always valid.

15
Gianocoli pg 570 Example 21-7: E at a point between two charges.
Two point charges are separated by a distance of 10.0 cm. One has a charge of
-25 μC and the other +50 μC. (a) Determine the direction and magnitude of the
electric field at a point P between the two charges that is 2.0 cm from the
negative charge. (b) If an electron (mass = 9.11 x 10-31 kg) is placed at rest at P
and then released, what will be its initial acceleration (direction and
magnitude)?

Point Charges
https://www.youtube.com/watch?v=p FM-a7_qjFM&t=3s

Problem solving in electrostatics: electric forces and electric fields
1. Draw a diagram; show all charges, with signs, and electric fields and forces with
directions.
2. Calculate forces using Coulomb’s law.
3. Add forces vectorially to get result.
4. Check your answer! General

16
 Giancoli page 570, Example 21-8: Electric field of two point charges.
Calculate the total electric field (a) at point A and (b) at point B in the figure
due to both charges, Q1 and Q2.

𝑚2
9.0 × 109 𝑁 50 × 10−6 𝐶
𝑘𝑄2 𝐶2
𝐸𝐴2 = = =

𝑚2
9.0 × 109 𝑁 −50 × 10−6 𝐶
𝑘𝑄1 𝐶2
𝐸𝐴1 = = =

𝐸𝐴𝑥 =

𝐸𝐴𝑦 =

𝐸𝐴 = 𝜃=

Solve for 𝐸𝐵 yourself
17
Point Charges
Electric fields of various systems of charges

Parallel Plates

https://www.youtube.com/w
atch?v=pOPQBlknBcM&t=3s

https://phet.colorado.edu/
en/simulati on/charges-
and-fields
Point Charges
18
Giancoli pg 572 Example 21-9: A ring of charge. [Non-Examinable]
A thin, ring-shaped object of radius a holds a total charge +Q distributed uniformly
around it. Determine the electric field at a point P on its axis, a distance x from the
center. Let λ be the charge per unit length (C/m).

𝑟= 𝑎2 + 𝑥 2

cos 𝜃 =

sin 𝜃 =
𝑄
A small segment of length 𝑑𝑙 has charge 𝑑𝑞 = 𝜆𝑑𝑙 where 𝜆 = 2𝜋𝑎

The contribution of charge 𝑑𝑞 to the magnitude of electric field at 𝑃 is

𝑘𝑑𝑞 𝑘𝜆𝑑𝑙
𝑑𝐸 = = 2
𝑟2 𝑟

𝑑𝐸 has two components - 𝑑𝐸⊥ and 𝑑𝐸𝑥

Summing up all the components perpendicular (⊥) to 𝑥 direction, we get

𝐸⊥ = 0

Summing up all the components along the 𝑥 direction, we get

𝑑𝑙
𝐸𝑥 = ∫ 𝑑𝐸𝑥 = න𝑑𝐸 cos 𝜃 = 𝑘𝜆 න cos 𝜃
𝑟2
2𝜋𝑎
𝑘𝜆
= 2 cos 𝜃 න 𝑑𝑙 =
𝑟 0

Check for reasonableness – when 𝑥 ≫ 𝑎, 𝐸 =

Point Charges -> Ring of charges 19
 2024S1 PH1012: Physics A
Electric Potential

Dr Ho Shen Yong
Lecturer, School of Physical and Mathematical Sciences
Nanyang Technological University

Week 8

Today is cruel and tomorrow is crueller. The day after tomorrow will be wonderful; however, most
people die on tomorrow night and won’t see the sunshine the day after tomorrow.
— From Ma Yun, CEO of Alibaba

Point Charges
Parallel Plates

2
General Δ𝑈 𝑥 = 𝑈2 − 𝑈1 = − න 𝐹𝑑𝑥
1

Point Charges
𝑄1𝑄2 𝑄1 𝑄2 1
𝐹റ 𝑒 = 𝑄2 𝐸

𝐹= 𝑈=.
𝑈 = 𝑄2 𝑉

4𝜋𝜀𝑜𝑟2 4𝜋𝜖𝑜 𝑟

𝑄1 1𝑄 1
𝐸= 𝑉 = 4𝜋𝜖.
4𝜋𝜀𝑜𝑟2 𝑜 𝑟
General
𝜕𝑉 General
𝐸𝑟 = −
𝐸 = 𝐸1 + 𝐸2 + 𝐸3 + ⋯ 𝜕𝑟 𝑉 = 𝑉1 + 𝑉2 + ⋯
https://www.youtube. https://www.youtu
com/watch?v=9 be.com/watch?v=1
kNkpQTwPc0&t=2s XI4D4SgHTw&t=2s
Electric force and electric potential energy
Earlier we learnt that the change in potential energy associated with a particular
conservative force 𝐹Ԧ as the negative of the work done by that force:
2
Δ𝑈 = 𝑈2 − 𝑈1 = − න 𝑭. 𝒅𝒍Ԧ = −𝑊
1

Remembering that integration and differentiation are inverse operations”

𝑑
න𝐹(𝑥) 𝑑𝑥 = 𝐹(𝑥)
𝑑𝑥

Thus,
𝑑𝑈 𝑥
𝐹 𝑥 =− General
𝑑𝑥

The same is applicable to the charges and electric field. Previously, it was mass
and the gravitational field.

Thus, electric potential energy can be written as
2
Δ𝑈𝐸 = 𝑈2 − 𝑈1 = − න 𝑭𝑬. 𝒅𝒍Ԧ General
1

We will consider the simplest electric field, the uniform field between two parallel
plates where the electric field is a constant value 𝐸 anywhere in between the
plates.
𝑏
Δ𝑈𝐸 = 𝑈𝑏 − 𝑈𝑎 = − න 𝑭𝑬. 𝒅𝒍Ԧ
𝑎

𝑏
𝟎 − 𝑼𝒂 = - ∫𝑎 𝒒𝑬𝒅𝒙 𝒄𝒐𝒔 𝟎∘

Parallel Plates
As in gravitational PE, we need to define a point
as zero PE. If the charge is –ve instead, the change in
electrical potential energy moving from a to b will be

Parallel Plates
21
Electric potential
Electric potential is defined as electrical potential energy per unit charge:
𝑈𝐸
𝑉= General
𝑞

Unit of electric potential: the volt (V):
1 V = 1 J/C. General

A simple numerical example:
If the separation of the two parallel plate is 𝑑 = 10 cm,
what is the electric potential at a point 3 cm from the positive plate?

Parallel Plates
What is the electric potential energy of an object with charge 𝑞 = 2 nC at this
point?

If the mass of the object is 0.01 kg, what is its velocity just before it hits the –ve
plate?

22
Electric potential energy 2
Consider two charges +𝑄1 and +𝑄2 at a distance 𝑟𝑖 apart. The position of one of
the charge is fixed while the other is free to move starting from rest at point i. A
repulsive force of magnitude
𝑄 𝑄
𝐹Ԧ = 1 2 2 𝑟Ƹ Point Charges
4𝜋𝜀 𝑟𝑜

acts between the protons while the free proton moves to a new position 𝑟𝑓.
𝑟𝑖 𝑟𝑓
𝑄1 𝑄2
+ + +

Fixed i f
The change in potential energy of charge 𝑄2 in the electric field of the fixed charge
𝑄1 is given by

𝑟𝑓 𝑟𝑓
Δ𝑈𝐸 = − න 𝐹Ԧ. 𝑑 𝑟Ԧ = − න 𝐹Ԧ 𝑑 𝑟Ԧ cos 0∘ General
𝑟𝑖 𝑟𝑖
𝑟𝑓
𝑄1 𝑄2
= −න 𝑑𝑟
𝑟𝑖 4𝜋𝜀𝑜𝑟2
𝑄1 𝑄2 𝑟𝑓 1 𝑄1 𝑄2 1 1
=− න 2 𝑑𝑟 = − − − −
4𝜋𝜀𝑜 𝑟𝑖 𝑟 4𝜋𝜀𝑜 𝑟𝑓 𝑟𝑖
𝑄1 𝑄2 1 1
= − =
4𝜋𝜀𝑜 𝑟𝑓 𝑟𝑖
Point Charges

As we would expect because the loss in electrical potential energy is transformed
to kinetic energy. If we fix the electrical potential energy at 𝑟𝑓 = ∞ as 𝑈𝐸 = 0,
then
𝑄1 𝑄2 1 1
𝑈𝑓 − 𝑈𝑖 = − Point Charges
4𝜋𝜀𝑜 𝑟𝑓 𝑟𝑖

𝑄1 𝑄2 1
⇒ for a general 𝑟 for Point Charges, 𝑈 =. As before, we can define
4𝜋𝜀𝑜 𝑟
the electric potential at a distance 𝑟 from of a point charge 𝑄 as

𝑈 𝑄
𝑉= = Point Charges
𝑞 4𝜋𝜀𝑜 𝑟

23
 Electric Field of Point charges

Point Charges

Giancoli pg 616, fig 23.17
The diagram shows the electric
field lines and the equipotential
lines of a positive point charge

Giancoli pg 613, fig 23.10/11
The electric potential of a charge 𝑄
as a function of distance 𝑟. Forces, Fields are vectors / scalars
General
Potential energy, potential are vectors / scalars

Uniform Electric Field

24
Parallel Plates
 Electric Field and Equipotential Lines

Parallel-plate Point charge Dipole

Electric
Field

Electric
Potential

25
Giancoli page 610, Example 23-2: Electron in CRT.
Suppose an electron in a cathode ray tube is accelerated from rest through a
potential difference Vb – Va = Vba = +5000 V. (a) What is the change in electric
potential energy of the electron? (b) What is the speed of the electron (m = 9.1 ×
10-31 kg) as a result of this acceleration?

26
Modified Giancoli pg 566 Example 21-2: Two charges in a line

Two charged particles are arranged in a line, as shown. Calculate the electric
potential at the point mark “x".

x

If a charge 𝑄3 (= +4.0 𝜇𝐶) is placed at “x”, calculate the electric potential energy
of 𝑄3.

The particle with 𝑄3 , mass 3.2 × 10−14 kg, is released from rest. What is its
velocity when it is 0.50 𝑚 from 𝑄2 ?

2.6 × 106 𝑚/𝑠

27
Modified Giancoli pg 566 Example 21-3:
Calculate the electric potential energy of charge 𝑄3 shown in the figure due to the
charges 𝑄1 and 𝑄2.

Electric potential V
We can also write the vectorial form of the definition for two points in 3-D space
𝑏 𝑏

𝑉𝑏 − 𝑉𝑎 = − න 𝐸. 𝑑 𝑠റ = − න(𝐸𝑥 𝑑𝑥 + 𝐸𝑦𝑑𝑦 + 𝐸𝑧𝑑𝑧)
𝑎 𝑎
Conversely, given the potential V(x, y, z), we can obtain the components of the
electric field
𝜕𝑉 𝜕𝑉 𝜕𝑉
𝐸𝑥 = − ; 𝐸𝑦 = − ; 𝐸𝑧 = −
𝜕𝑥 𝜕𝑦 𝜕𝑧
𝜕𝑉
Here, 𝜕𝑥 denotes a partial derivative – differentiating w.r.t. x and treating variables
𝜕𝑉 𝜕𝑉
y and z in V as constants. It applies similarly to 𝜕𝑦 and 𝜕𝑧. If the electric field only
varies in the radial direction with r, then
𝜕𝑉
𝐸𝑟 = −.
𝜕𝑟
The negative sign is associated with the fact that the electric field is always
pointing from higher potential to lower potential. We note that another unit for
the electric field is volts per metre (V/m).

28
Electric Field and Electric Potential

http://dev.physicslab.org/Document.aspx?doctype=3&filename=Electrostatics_PointChargesEPE.xml

i. Where is the electric field strongest? L, M, N, R, S, T, U

ii. Where is the electric field weakest? L, M, N, R, S, T, U

iii. What is the direction of the electric field at R?

iv. How much work would it take an external agent to move a charge 2 𝜇C
from R to N?

v. Does it take more work to move a 2 µC charge from R to L and then to T
compared to going directly to T?

vi. How much EPE did the 2 µC charge have while it was at rest at position R?

vii. What is the 2 µC charge’s EPE at point T?

viii. How much work was required to move the 2 µC charge from R to T?

29
 Force, Field and Flux

𝑛ො

Area A
Force, 𝐹Ԧ Field Lines, 𝐸
Flux Φ𝐸

𝐹Ԧ = 𝑞𝐸 Φ𝐸 = න𝐸. 𝑑 𝐴መ
𝑑𝑉
𝐸=−
𝑑𝑟

Force + Field
𝑑𝑈
𝐹Ԧ = −
𝑑𝑟 Equipotential Lines 𝑉
𝑈 = 𝑞𝑉

Using dipole as example

Potential Energy

[email protected]
 2024S1 PH1012: Physics A
Gauss’s Law

Dr Ho Shen Yong
Lecturer, School of Physical and Mathematical Sciences
Nanyang Technological University

Week 8/9

"Genius is one percent inspiration, ninety-nine percent perspiration."
- Thomas Alva Edison (1847-1931)

E-field / potential of Gauss’s Law
system of charges

Electrostatic https://www.youtub
equilibrium e.com/watch?v=p
qTfk9HMLj4&t=2s
Three key charge
distributions related
charge storing
configurations
Giancoli pg 573, Example 21.11:
Electric field due to a long line of charge

Determine the magnitude of the electric field at
any point P a distance x from a very long line (a
wire, say) of uniformly distributed charge.
Assume x is much smaller than the length of the
wire, and let λ be the charge per unit length
(C/m).

1 𝑑𝑄 1 𝜆𝑑𝑦
𝑑𝐸 = =
4𝜋𝜀𝑜 𝑟 2 4𝜋𝜀𝑜 (𝑥 2 + 𝑦 2 )

𝑃 is along bisector of rod so 𝑦 component of 𝐸 is zero.
𝐸𝑦 = ∫ 𝑑𝐸 sin 𝜃 = 0

Along the 𝑥 direction,
𝜆 cos 𝜃 𝑑𝑦
𝐸𝑥 = ∫ 𝑑𝐸 cos 𝜃 = න 2 =…
4𝜋𝜀𝑜 𝑥 + 𝑦2

For an infinitely long wire,
𝜆
𝐸=
2𝜋𝜀𝑜 𝑥

Is there an easier way to work out the electric field of an infinitely
long line of charge?

32
Giancoli pg 592 Example 22-1
Calculate the electric flux through the rectangle shown. The rectangle is 10 cm
by 20 cm, the electric field is uniform at 200 N/C, and the angle θ is 30°.

Non-uniform field and/or flux through curved surfaces
In general, when the field is not uniform and/or if the surface is not flat, we
have to divide up the chosen surface into 𝑛 smaller patches of area Δ𝐴1 , Δ𝐴2 , …
small enough that
1) it can be considered (nearly) flat
2) the variation of the field over the
selected area is (nearly) constant.

Thus, the entire (electric) flux ΦE over the surface is
𝑛

Φ𝐸 ≈ ෍ 𝐸𝑖. Δ𝐴Ԧ𝑖
𝑖=1
where 𝐸 is the field passing through area Δ𝐴Ԧ𝑖. In the limit, where the elemental
area is infinitesimally small Δ𝐴Ԧ𝑖 → 0, the 𝐸 is constant and we have to move
from a discrete sum to continuous sum
Φ𝐸 = න𝐸. 𝑑 𝐴Ԧ.
Later, we will be dealing with total flux through
closed surface – a surface of any shape that
completely encloses a volume of space, we write
Φ𝐸 = ර𝐸. 𝑑 𝐴Ԧ
Here, the symbol ‫ׯ‬ denotes an integral over a closed surface.
33
 Revising the Concept of Flux

Heavy Rain – “high rain flux per unit area” Light Rain – “low rain flux per unit area”
(high flux density) (low flux density)
http://99fm.com.na/unseasonably-heavy-rain-expected/ http://www.chachacharming.com/music/i-like-london-in-the-rain-mix/

𝑓𝑙𝑢𝑥 𝑑𝑒𝑛𝑠𝑖𝑡𝑦, 𝑓Ԧ

𝑛ො

Area A 𝜃 𝜃′
Vector area 𝐴𝑛ො Projected area
“shadow”
[email protected]
Total flux “captured” by area Φ = “flux density”× Projected Area
= “flux density”× Area 𝑐𝑜𝑠 𝜃
= 𝐴 𝑓Ԧ 𝑛ො cos 𝜃 = 𝑓.Ԧ 𝐴𝑛ො Earlier discussion on
gravitational fields:
Ԧ
For curved surface, 𝑑 𝐴 = 𝐴𝑑𝑛
Ԧ 𝑑 𝐴Ԧ
𝑇𝑜𝑡𝑎𝑙 𝑓𝑙𝑢𝑥, Φ = න𝑓.
For closed curved surface, (convention, outwards +ve)

Ԧ 𝑑 𝐴Ԧ
𝑇𝑜𝑡𝑎𝑙 𝑓𝑙𝑢𝑥, Φ = ර𝑓.
Thus, for electric fields, the total electric flux Φ𝐸 http://commons.wikimedia.or
passing through an imaginary surface g/wiki/File:Gravitational_field_
Earth_lines_equipotentials.svg
(“Gaussian surface”) is given by
Φ𝐸 = ර𝐸. 𝑑 𝐴Ԧ Ԧ 𝑑𝐴Ԧ
Φ𝐺 = ර𝑔.
34
A simple example

This all can look complicated later but let us try it on something not too difficult first.
Consider a charge 𝑄 = 1.2nC enclosed by an imaginary sphere of radius 10 cm with
the charge in the centre of the sphere. Calculate the total electric flux that goes
through the surface of the sphere. [Note here that electric field the magnitude of
the electric field is constant on the surface and the elemental area 𝑑 𝐴Ԧ is parallel to
the 𝐸 at all points on the sphere.]

[Convention: Flux leaving enclosed volume is +ve
Flux entering enclosed volume is –ve. This convention is consistent with E-field
pointing away from +ve charge and towards –ve charge.]

What is the total electric flux if a large sphere of 20 cm is used?

What is the total electric flux if Q is replaced with a –ve charge with the same
magnitude?

How will the total electric flux change if the charge is placed in the centre of a cube
of sides 6 cm instead?

How will the total electric flux change if the charge is not in the center of sphere or
the cube?

35
Giancoli pg 593, 22-2 Gauss’s Law

The precise relationship between the electric flux through a closed surface (Gaussian surface)
and the net charge enclosed within that surface is given by Gauss’s Law:

𝑄𝑒𝑛𝑐
Φ𝐸 = ර𝐸. 𝑑𝐴Ԧ =
𝜖

where 𝜖 is permittivity as mentioned previously. In principle, Gauss’s law can be used to find
the expression for 𝐸 for a system of charge or charge distribution. However, in practice, the
application of Gauss’s law is only limited to a number of highly symmetric electric fields. On
the other hand, Gauss’s law gives us a simple perception so that we can deal easily with
situations such as when there are charges within the interior of a hollow sphere etc.

Why was that point charge / sphere example simple?
1. The magnitude of the electric field is constant on the surface and
2. the elemental area 𝑑𝐴Ԧ is parallel to the 𝐸 at all points on the surface.

What are the other simple examples?
1. Point (Charge)
2. (Very long) Line (Charge per unit length, 𝜆)
3. (Very Wide) Plane (Charge per unit area, 𝜎)
4. 3D Sphere (Charge per unit volume, 𝜌)

36
Symmetry and regions of constant electric field

Total flux through surface of
‘imaginary’ sphere of radius 𝑟 = 𝟒𝝅𝒓𝟐 𝑬𝒑𝒕
Total charge enclosed = 𝑸

Applying Gauss’s Law,

Wire with uniform charge per unit length = 𝜆

Total flux through surface of ‘imaginary’ cylinder
of radius 𝑟 and length 𝑙 = 2𝝅𝑹𝒍𝑬𝑳
Total charge enclosed = 𝝀𝒍

Applying Gauss’s Law,

Conducting Plate with charge per unit area = 𝜎

Total flux through surface of ‘imaginary’ disc
of cross sectional area 𝐴 = 𝟐𝑬𝒑𝒍 𝑨
Total charge enclosed = 𝝈𝑨

Applying Gauss’s Law,

Solid sphere of insulator with uniform charge density = 𝜌

Total flux through surface of ‘imaginary’ sphere with
radius 𝑟1 (> 𝑟𝑜 ) = 𝟒𝝅𝒓𝟐𝟏 𝑬𝒔𝒑,𝒆𝒙𝒕
𝟒
Total charge enclosed = 𝝆 𝝅𝒓𝟑𝒐 =𝑸
𝟑

Applying Gauss’s Law,

37
Spherically Symmetric Charge Distribution
[Giancoli pg 596 Example 22-4]
An electric charge Q is distributed uniformly throughout a nonconducting sphere of
radius r0. Determine the electric field
(a) outside the sphere (r > r0) and
(b) inside the sphere (r < r0).

Mathematical concept test:
A sphere has mass M. What is the mass of a sphere
made of the same material but double the radius?

b) Total flux (outwards)
through Gaussian surface 𝐴2 = _______________

Total charge enclosed by
Gaussian surface 𝐴2 = _______________

Applying Gauss’s Law:

c.f Notes on gravitation – what is the g-field
inside Earth.

38
Electric Field inside conductor at Electrostatic Equilibrium I
[Giancoli pg 577, 598-600]

Electrostatic equilibrium – The electric field inside a conductor is zero when the
conductor is in electrostatic equilibrium - charges are at rest. If there is a non-zero
electric field within the conductor, there would be a force on the free electrons. The
electrons would move until they reached positions where the electric field, hence
electric force on them, become zero.
A few consequences at electrostatic equilibrium:

1. The electric field is zero everywhere inside the conductor (hollow or solid).

2. If conductor is isolated, any net charge will distribute itself on the surface.
−
− Recall
−
− − −
−
− −

𝐸=0
− −
−

conductor Charges deposited Charges redistributed on
on conductor conductor such that E-
field in conductor is zero
Google homework: Faraday cage.

3. If a charge (say +𝑄) is surrounded by
an isolated uncharged conducting
spherical shell, applying Gauss’s law
with the Gaussian surface inside the
conductor,

We can infer that there is

Since the shell is neutral,

Though no field exists inside conductor, an E-field exists outside of it, as if the
conducting spherical shell were not there.
39
Electric Field inside conductor at Electrostatic Equilibrium II
[Giancoli pg 577, 598-600]

A few consequences at electrostatic equilibrium:

4. The electric field near the surface of the conductor points perpendicular to the
surface. If the electric field 𝐸 at the surface of a conductor had a component
parallel to the surface 𝐸|| it would exert a force on the electrons at the
surface causing electrons to move along surface until the net force on the
system of free charges become zero. Only the component of the electric field
perpendicular to the surface 𝐸Ԧ⊥ will not vanish.

𝐸⊥ ≠ 0

𝐸|| = 0

No in electrostatic equilibrium In electrostatic equilibrium
5. For irregularly shaped conductor, the surface density is greatest at locations
where the radius of curvature of the surface is smallest.

http://www.kshitij-iitjee.com/electric-potential-due-to-
charged-conductor

40
Giancoli pg 577 Conceptual Example 21-14: Shielding, and safety in a storm.
A neutral hollow metal box is placed between two parallel charged plates as shown.
What is the field like inside the box?

Three possible cases whereby 𝚽𝐄 = 𝟎

For 𝐴2 Here,

Φ𝐸 = ර 𝐸 ∙ d𝐴റ = 0 Φ𝐸 = ර 𝐸 ∙ d𝐴റ =
Φ𝐸 = ර 𝐸 ∙ d𝐴റ = 0

and here 𝐸 and here 𝐸 and here 𝐸
Net charge enclosed = Net charge enclosed = Net charge enclosed =
41
Electric Field of Parallel plates

42