Applied Physics Past Paper PDF 24PH101T 2024

Summary

This document is a set of applied physics lecture notes, covering topics such as magnetic fields, Lorentz force, Biot-Savart's law, and provides examples and problems to solve. The document's title is Applied Physics, and the included date is August 19, 2024.

Full Transcript

Applied Physics
Course Code: 24PH101T

Applied Physics August 19, 2024 1 / 44
Outline

4 Divergence and Curl of Mangetic
1 Introduction – Magnetic Fields
Field
2 Lorentz Force Law
3 Biot Savart’s law 5 Problems (Magnetostatics)

Applied Physics August 19, 2024 2 / 44
Introduction – (1)

Two wires hang from the ceiling, a
few centimeters apart

When the current is turned on, so
that it passes up one wire and
back down the other, the wires
jump apart.

Suppose that the battery is actually charging up the wire, and that the
force is simply due to the electrical repulsion of like charges.

If a test charge is placed near these wires, there would be no force on it,
for the wires are in fact electrically neutral.

Applied Physics August 19, 2024 3 / 44
Introduction – (2)

If the demonstration is set up so as
to make the current flow up in
both wires.

The wires are found to attract

Conclusion
Whatever force accounts for the attraction of parallel currents and the
repulsion of anti-parallel ones is not electrostatic in nature.

Applied Physics August 19, 2024 4 / 44
Lorentz Force Law

Magnetic Force
The magnetic force on a charge Q, moving with velocity, ⃗v in a magnetic
⃗ is given by,
field B  
⃗ = Q ⃗v × B
Fmag ⃗

Lorentz Force
In presence of both electric and magnetic field, the force on charge Q is,
h  i
F⃗ = Q E⃗ + ⃗v × B ⃗

There is no derivation. It is a fundamental axiom of the theory.

It is a peculiar law, and it leads to some truly bizarre particle trajectories.

Applied Physics August 19, 2024 5 / 44
Example 1 – Cyclotron Motion – (1)

The archtypical motion of a charged particle
in a magnetic field is circular, with the
magnetic force providing the centripetal
acceleration.

A uniform magnetic field points into the
page; if the charge Q moves
counterclockwise, with speed ⃗v , around a
circle of radius R.
Lorentz Force
  For circular motion, the mechanical force is
⃗
F⃗ = Q ⃗v × B given by,
mv 2
F = QvB sinθ = QvB F = , here, m is mass of the particle, p
R
is its momentum.

Applied Physics August 19, 2024 6 / 44
Example 1 – Cyclotron Motion – (2)

Equating the two forces,

mv 2
= QvB
R
p = QBR
The charge moves in a plane
It also suggests a simple ⃗ If it starts out
perpendicular to B.
experimental technique for finding with some additional speed ⃗v||
the momentum of a charged ⃗ this component of
parallel to B,
particle: send it through a region
the motion is unaffected by the
of known magnetic field, and
magnetic field, and the particle
measure the radius of its trajectory.
moves in a helix

Applied Physics August 19, 2024 7 / 44
Example 2 : “e/m” by Thomson’s Method – (1)

In 1897, J. J. Thomson “discovered” the electron by measuring the
charge-to-mass ratio of “cathode rays”.

Part A:
First he passed the beam through uniform crossed electric and magnetic
fields E⃗ and B
⃗ (mutually perpendicular, and both of them perpendicular to
the beam), and adjusted the electric field until he got zero deflection.
What, then, was the speed of the particles (in terms of E⃗ and B)?
⃗

If the electron is travelling along Z-axis with velocity, ⃗v = v zb
The electric field is along X-axis, E⃗ = E xb
⃗ = B yb
The magnetic field is along Y-axis, B

Applied Physics August 19, 2024 8 / 44
Example 2 : “e/m” by Thomson’s Method – (2)

Using Lorentz force,
h  i
F⃗ = Q E⃗ + ⃗v × B⃗ = Q [E xb + (v zb × B yb)] = Q (E xb − vB yb)

Since there is zero deflection, the total force is zero,
E
Q (E xb − vB yb) = 0 =⇒ v =
B

Part B
Then he turned off the electric field, and measured the radius of curvature,
R, of the beam, as deflected by the magnetic field alone. In terms of E ,
B, and R, what is the charge-to-mass ratio (q/m) of the particles?

Applied Physics August 19, 2024 9 / 44
Example 2 : “e/m” by Thomson’s Method – (3)

If mass of the particle is M, the momentum is given by Mv

The momentum as calculated by the radius of curvature,

Mv = QBR

Simplyfying,
Q v
=
M BR

Q E
=⇒ = 2
M B R

Applied Physics August 19, 2024 10 / 44
Currents – (1)

Definition:
The current in a wire is the charge per unit time passing a given point.

Negative charges moving to the left count the same as positive ones to the
right.

In practice, it is ordinarily the negatively charged electrons that do the
moving-in the direction opposite to the electric current.

To avoid the petty complications this entails, it is often pretended that it’s
the positive charges that move.

Current is measured in coulombs-per-second, or amperes (A).

Applied Physics August 19, 2024 11 / 44
Currents – (2)

Current is actually a vector: ⃗I = λ⃗v , but
the path of the flow is dictated by the
shape of the wire, one doesn’t ordinarily
bother to display the direction of I
A line charge λ traveling explicitly.
down a wire at speed v
constitutes a current The magnetic force on a segment of
current -carrying wire is,
I = λv Z  Z 
 
⃗
F = ⃗
⃗v × B dq = ⃗ λdl
⃗v × B
because a segment of
length v ∆t, carrying Z  
charge λv ∆t, passes point F⃗ = ⃗I × B
⃗ dl
P in a time interval ∆t.

Applied Physics August 19, 2024 12 / 44
Currents – (3)

In as much as ⃗I and d ⃗l both point in the same direction, it can be written
this as, Z  
⃗
F = I d ⃗l × B ⃗

Typically, the current is constant (in magnitude) along the wire, and in
that case I comes outside the integral:
Z
F = I d ⃗l × B
⃗ ⃗

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Currents – (4)

⃗ is the current per unit width.
K

If the surface charge density is σ
and its velocity is ⃗v , then
⃗ = σ⃗v
K
Surface current density
Consider a “ribbon” of The magnetic force on the surface
infinitesimal width dl⊥ , running current is,
parallel to the flow with current Z  
flowing through it, d ⃗I , F⃗ = ⃗ σda
⃗v × B
⃗
⃗ = dI
Z  
K F⃗ = ⃗ ×B
K ⃗ da
dl⊥

Applied Physics August 19, 2024 14 / 44
Currents – (5)

J⃗ is the current per unit area.

If the volume charge density is ρ
and the velocity is ⃗v , then

J⃗ = ρ⃗v
Volume current density
Consider a “tube” of infinitesimal The magnetic force on the surface
cross section da⊥ , running parallel current is,
to the flow with the current d ⃗I Z  
flowing in the tube, ⃗
F = ⃗ ρdτ
⃗v × B

d ⃗I Z 
J⃗ =

da⊥ F⃗ = J⃗ × B
⃗ dτ

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Example 3

Suppose the current density in the wire
is proportional to the distance from the
axis, J = ks zb (for some constant k).
Find the total current in the wire.

Because J varies with s, it Z
must be integrated, ∴I = (ks) (s ds dϕ)
Z Z a Z 2π
2
I = J⃗ · d⃗a⊥ =k s ds dϕ
0 3  0
a
=k 2π
3
d⃗a⊥ = s ds dϕ zb
2πka3
=
3

Applied Physics August 19, 2024 16 / 44
Steady Currents

Stationary Charges Steady Currents
=⇒ Constant electric fields =⇒ Constant magnetic fields
=⇒ ELECTROSTATICS =⇒ MAGNETOSTATICS

Steady current means
A continuous flow that has been going on forever, without change and
without charge piling up anywhere.

Formally, for electro/magnetostatics is the regime of

∂ρ ∂ J⃗
=0, =0
∂t ∂t

When a steady current flows in a wire, its magnitude I must be the same
all along the line; otherwise, charge would be piling up somewhere,
=⇒ ∇ ⃗ · J⃗ = 0
Applied Physics August 19, 2024 17 / 44
Biot Savart’s Law – (1)

The magnetic field of a steady line current is given by
r r
Z ⃗
I ×c d ⃗l ′ × c
Z
⃗ (⃗r ) = µ0
B ′
dl =
µ0 I
4π r 2 4π r 2

The integration is along the
current path, in the direction of
the flow; d ⃗l ′ is an element of
length along the wire.

The constant µ0 is called the
permeability of free space,
µ0 = 4π × 10−7 NA−2.

Applied Physics August 19, 2024 18 / 44
Biot Savart’s Law – (2)

⃗
Unit of B For Surface Currents,
Newtons per ampere-meter –
N/ (A · m) or Teslas, T.
r ′
 
⃗ r⃗′ × c
Z K
⃗ (⃗r ) = µ0
B da
As the starting point for 4π r2
magnetostatics, the Biot-Savart
law plays a role analogous to For Volume Currents,
Coulomb’s law in electrostatics.
r ′
 
Z J⃗ r⃗′ × c
⃗ (⃗r ) = µ0
The 1/ r 2 dependence is common B
4π r2
dτ
to both laws.

The superposition principle applies to magnetic fields just as it does to
electric fields.

Applied Physics August 19, 2024 19 / 44
Example 4 – (1)

Find the magnetic field a distance s from
a long straight wire carrying a steady
current I.

Biot Savart’s Law

r
d ⃗l ′ × c d ⃗l ′ × r⃗
Z Z
⃗ = µ0 I
B =
µ0 I
′
⃗r = s sb , r⃗′ = l zb 4π r 2 4π r 3

d ⃗l ′ = dl ′ zb
r⃗ = ⃗r − r⃗′ = s sb − l ′ zb Approaching the problem in Cylindrical
Coordinates, assuming the wire is placed
r = s 2 + l ′2 1/2


along the Z-axis and the point P is on
XY-plane.
r 3 = s 2 + l ′2 3/2

Applied Physics August 19, 2024 20 / 44
Example 4 – (2)

d ⃗l ′ × r⃗ = dl ′ zb × s sb − l ′ zb

= dl ′ s ϕb

Substituting...
dl ′ s ϕb
Z
⃗ = µ0 I
B
4π (s 2 + l ′2 )3/2
If a zb and b zb substitute an angle
of θ1 and θ2 , as shown in Figure.
If a zb and b zb are two points on
the line with a < b l ′ = s tanθ
µ0 Is b
Z
dl ′ s
⃗
B= ϕb dl ′ = s sec2 θ dθ = dθ
4π a (s 2 + l ′2 )3/2 cos2 θ

Applied Physics August 19, 2024 21 / 44
Example 4 – (3)

Z θ2
⃗ = µ0 Is
∴B
1 s
dθ ϕb
4π θ1 (s 2 + s 2 tan2 θ) 3/2 cos2 θ
θ2
µ0 Is 2
Z
µ0 I
= cosθ dθ ϕb = (sinθ2 − sinθ1 ) ϕb
4πs 3 θ1 4πs

This is a solution for a line segment located on a wire.

For infinite wire, θ1 = −π/2 and θ2 = π/2.

⃗= µ0 I b
∴B ϕ
4πs

Applied Physics August 19, 2024 22 / 44
Example 5 – (1)

Find the magnetic field a distance z above the
center of a circular loop of radius R, which carries
a steady current I.

Idea is...
⃗ attributable to the segment d ⃗l ′
The field d B
points as shown. As it is integrated around the
⃗ sweeps out a cone. The horizontal
loop, d B
components cancel, and the vertical components
combine along Z-axis.

Approaching the problem in Cylindrical coordinates...

Applied Physics August 19, 2024 23 / 44
Example 5 – (2)

Biot Savart’s Law
d ⃗l ′ × r⃗ d ⃗l ′ × r⃗ = Rdϕ ϕb × (−R sb + z zb)
Z
⃗ = µ0 I
B
4π r 3
= R 2 dϕ zb

From figure Substituting...
r⃗′ = R sb Z 2π
⃗ µ0 I R2
⃗r = z zb B= dϕ zb
4π (R 2 + z 2 )3/2 0
r⃗ = −R sb + z zb
µ0 I R2
d ⃗l ′ = Rdϕ ϕb = 2π zb
4π (R 2 + z 2 )3/2
r = R 2 + z 2 1/2


µ0 I R2
= zb
r 3 = R 2 + z 2 3/2 2 (R 2 + z 2 )3/2

Applied Physics August 19, 2024 24 / 44
Straight Line Currents – (1)

The magnetic field of an infinite
straight wire is shown.

At a glance, it is clear that this
field has a nonzero curl.

⃗ around a circular
The integral of B
path of radius s,

I I I
⃗ · d ⃗l = µ0 I µ0 I
B dl = dl = µ0 I
2πs 2πs

Applied Physics August 19, 2024 25 / 44
Straight Line Currents – (2)

Notice that the answer is
independent of s; that’s because B⃗
Computing integral,
decreases at the same rate as the I I
circumference increases. ⃗ ⃗ µ0 I 1
B · dl = sdϕ
2π s
Using Cylindrical coordinates, µ0 I 2π
Z
= dϕ = µ0 I
2π 0
d ⃗l = dsb
s + sdϕϕb + dz zb

This assumes the loop encircles
Magnetic field for current flowing the wire exactly once; if it went
along z-axis, around twice, then ϕ would run
from 0 to 4π.
⃗ = µ0 I ϕb
B
2πs

Applied Physics August 19, 2024 26 / 44
Straight Line Currents – (3)
R
If it didn’t enclose the wire at all, then dϕ = 0.

There is a bundle of straight wires.
Each wire that passes through the
loop contributes µ0 I , and those
outside contribute nothing.

The line integral will then be,
I
⃗ · d ⃗l = µ0 Ienc
B

If the flow of charge is represented ⃗ the
by a volume current density J,
⃗
R
enclosed current is, Ienc = J · d⃗a.

Applied Physics August 19, 2024 27 / 44
Curl of Magnetic Field

Using the formula of enclosed current shown as integral of volume current
density, in the equation of closed loop integral,
I Z
B · d l = µ0 J⃗ · d⃗a
⃗ ⃗

Applying Stoke’s law,
I Z   Z
⃗ ⃗
B · dl = ∇ × B · d⃗a = µ0 J⃗ · d⃗a
⃗ ⃗
S

Hence,
⃗ = µ0 J⃗
⃗ ×B
∇

Applied Physics August 19, 2024 28 / 44
Ampere’s Law

The equation for the curl of B,
⃗ = µ0 J,
⃗ ×B
∇ ⃗

is called Ampere’s law (in differential form).

Taking a surface integral, The line integral is along Rthe
Z   Z boundary of the surface. S J⃗ · d⃗a
∇ × B · d⃗a = µ0 J⃗ · d⃗a
⃗ ⃗ is the total current passing
S S through the cross section area.

Applying Stoke’s law to LHS, I
I Z ⃗ · d ⃗l = µ0 Ienc
B
B · d l = µ0 J⃗ · d⃗a
⃗ ⃗
S Ampere’s Law (integral form)

Applied Physics August 19, 2024 29 / 44
Ampere’s Law (Discussion)

The integral form of Ampere’s Law inherits the sign ambiguity of the
Stoke’s theorem.
Which way around the loop is the integration supposed to be calculated?

And which direction through the surface corresponds to a “ positive”
current?

The answer, as always, is the right-hand rule.

If the fingers of the right hand indicate the direction of integration around
the boundary, then your thumb defines the direction of a positive current.

For currents with appropriate symmetry, Ampere’s law in integral form
offers a lovely and extraordinarily efficient way of calculating the magnetic
field.
Applied Physics August 19, 2024 30 / 44
Example 6

Find the magnetic field a distance s from a long straight
wire, carrying a steady current I.

By Right Hand Rule...
⃗ is found to be “circumferential”
The direction of B

I
Amperian Loop is a circle of radius ⃗ · d ⃗l = µ0 Ienc
B
s around the wire. Z 2π
B s dϕ = µ0 I
Using Cylindrical System, 0
B2πs = µ0 I
⃗ = B ϕb , d ⃗l = s dϕ ϕb
B µ0 I
B=
2πs

Applied Physics August 19, 2024 31 / 44
Example 7 – (1)

Find the magnetic field of an infinite
⃗ = K xb,
uniform surface current K
flowing over the XY-plane.

⃗
What is the direction of B?

Biot Savart’s Law ⃗ can only be having Y- and
B
Z-components.
r ′
 
⃗ r⃗′ × c
Z K ⃗ = By yb + Bz zb
⃗ (⃗r ) = µ0 B
B da
4π r2
Amperian Loop to be put up in
⃗ ⊥K
=⇒ B ⃗
YZ-plane.

Applied Physics August 19, 2024 32 / 44
Example 7 – (2)

Amperian loop is a rectangle with four components.
d l⃗1 = −dy yb – for line segment above the XY-plane.
d l⃗2 = −dz zb – for line segment left of the XZ-plane.
d l⃗3 = dy yb – for line segment below the XY-plane.
d l⃗4 = dz zb – for line segment right of the XZ-plane.
I Z Z Z Z
⃗ ⃗ ⃗ ⃗ ⃗ ⃗ ⃗
∴ B · d l = B · d l1 + B · d l2 + B · d l3 + B ⃗ ⃗ · d l⃗4
1 2 3 4

For path 2 For path 4
⃗ · d l⃗2 = 0
B ⃗ · d l⃗4 = 0
B

This shows that for the vertical line, the contribution from Current cancels
each other out.

Applied Physics August 19, 2024 33 / 44
Example 7 – (3)

For path 1
Z Z
⃗ · d l⃗1 = By dy =⇒
B ⃗ · d l⃗1 =
B By dy = By l
1 1

For path 3
⃗ = −By yb
Here, B
Z Z
⃗ · d l⃗3 = By dy =⇒
B ⃗ · d l⃗3 =
B By dy = By l
3 1

Applied Physics August 19, 2024 34 / 44
Example 7 – (4)

Using Ampere’s Law,
I
∴ ⃗ · d ⃗l = 2 By l = µ0 K l
B
µ0 K
∴ By =
2

Hence the Magnetic field is given by,

+ µ0 K yb,

for z > 0
⃗
B= 2
µ K
− 0
 yb, for z < 0
2

Applied Physics August 19, 2024 35 / 44
Example 8 – (1)

Find the magnetic field of a very long
solenoid, consisting of n closely wound turns
per unit length on a cylinder of radius R, each
carrying a steady current I.

Magnetic field is of the form,
⃗ = Bs sb + Bϕ ϕb + Bz zb
B

d ⃗l = ds sb + s dϕ ϕb + dz zb

⃗ · d ⃗l = Bs ds + Bϕ s dϕ + Bz dz
∴B

Applied Physics August 19, 2024 36 / 44
Example 8 – (2)

⃗ ⊥K
Using B ⃗
Since, the current is going around a circle, it can be
written as,
K⃗ = Ks sb + Kϕ ϕb

This information concludes that the magnetic field is
⃗ = Bz zb.
along Z-direction. ∴ B

⃗ · d ⃗l
Only the 3rd term survives in the B

To find the magnetic field inside and outside the solenoid two Amperian
loops are used. One entirely outside and another partially inside and
partially outside.

Applied Physics August 19, 2024 37 / 44
Example 8 – (3)

For Loop 1
I
⃗ · d ⃗l = [Bz (a) − Bz (b)] L = µ0 Ienc = 0
B

=⇒ Bz (a) = Bz (b)

Evidently the field outside does not depend on
the distance from the axis.

For Loop 2
I
⃗ · d ⃗l = Bz L = µ0 Ienc = µ0 n I L =⇒ Bz = µ0 nI , ∴ B
B ⃗ = µ0 nI zb

Applied Physics August 19, 2024 38 / 44
Comparison of Electrostatics and Magnetostatics

Electrostatics Magnetostatics
=⇒ Stationary Charges =⇒ Steady Currents
=⇒ Constant electric fields =⇒ Constant magnetic fields
=⇒ Coulomb’s Law =⇒ Biot Savart’s Law
=⇒ Gauss’s Law =⇒ Ampere’s Law
⃗ · E⃗ = ρ
∇ ⃗ = µ0 J⃗
⃗ ×B
ϵ0 ∇
I I
Qenc ⃗ · d ⃗l = µ0 Ienc
E⃗ · d⃗a = B
S ϵ0
⃗ × E⃗ = 0 =⇒ ∇ ⃗ =0
⃗ ·B
=⇒ ∇

Applied Physics August 19, 2024 39 / 44
Problems for Homework – (1)

Problem 1
A particle of charge q enters a region of
uniform magnetic field B⃗ (pointing into the
page). The field deflects the particle a
distance d above the original line of flight.
Is the charge positive or negative? In terms
⃗ and q, find the momentum of
of a, d, B
the particle.

Problem 2
Suppose that the magnetic field in some region has the form B ⃗ = kz zb
(where k is a constant). Find the force on a square loop (side a), lying in
the YZ–plane and centered at the origin, if it carries a current I , flowing
counterclockwise, when you look down the X–axis.

Applied Physics August 19, 2024 40 / 44
Problems for Homework – (2)

Problem 3
A current I flows down a wire of radius a.
1 If it is uniformly distributed over the surface, what is the surface
current density K ⃗?
2 If it is distributed in such a way that the volume current density is
inversely proportional to the distance from the axis, what is J⃗ (s)?

Problem 4
Find the magnetic field at the center of a
square loop, which carries a steady current I.
Let R be the distance from center to side.

Applied Physics August 19, 2024 41 / 44
Problems for Homework – (3)

Problem 5
Find the magnetic field at point P on the axis of a tightly wound solenoid
(helical coil) consisting of n turns per unit length wrapped around a
cylindrical tube of radius a and carrying current I. Express your answer in
terms of θ1 and θ2 (it’s easiest that way). Consider the turns to be
essentially circular, and use the result of Example 6. What is the field on
the axis of an infinite solenoid (infinite in both directions)?

Applied Physics August 19, 2024 42 / 44
Problems for Homework – (4)

Problem 6
A steady current I flows down a long cylindrical
wire of radius a. Find the magnetic field, both
inside and outside the wire, if

1 The current is uniformly distributed over the outside surface of the
wire.
2 The current is distributed in such a way that J⃗ is proportional to s,
the distance from the axis.

Problem 7
A thick slab extending from z = −a to z = +a (and
infinite in the X and Y directions) carries a uniform
volume current J⃗ = J xb. Find the magnetic field, as a
function of z, both inside and outside the slab.
Applied Physics August 19, 2024 43 / 44
Problems for Homework – (5)

Problem 8
Analyze the motion of a particle (charge q, mass m) in the magnetic field
of a long straight wire carrying a steady current I.
1 Is its kinetic energy conserved?
2 Find the force on the particle, in cylindrical coordinates, with I along
the Z axis.
3 Obtain the equations of motion.
dz
4 Suppose dt is constant. Describe the motion.

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