Post on 16-Dec-2020
Magnetostatic Fields
Dr. Talal Skaik Islamic University of Gaza – Palestine
2012
2
Introduction In chapters 4 to 6, static electric fields characterized by E or D
(D=εE) were discussed.
This chapter considers static magnetic fields, characterised by H
or B (B=μH).
As we have noticed, a distribution of static or stationary charges
produces static electric field.
If the charges move at a constant rate (direct current- DC), a
static magnetic field is produced (magnetostatic field).
Static magnetic field are also produced by stationary permanent
magnets.
3
A compass needle is deflected by the direct current flowing in a conductor
Magnetic Field Around Current Carrying Wires
The iron filings form circles around the wire along the magnetic field
6
Electrostatic Fields have dual equations for magnetostatic fields
Biot-Savart’s law states that the magnetic field intensity dH produced at a point P by a differential current element Idl is proportional to the product Idl and the sine of the angle α between the element and the line joining P to the element and is inversely proportional to the square of the distance R between P and the element and its direction can be obtained by right handed screw rule.
Biot-Savart’s Law
7
2
2
2
sin
sin = , 1/ 4
sin=
4
I dldH
R
kI dlor dH k
R
I dldH
R
8
2
2 3
R
sin=
4
l l RH
4 4
where =|R| and a =R/
R
I dldH
R
I d a I dd
R R
R R
The direction of dH can be determined by the right-hand rule or right-handed screw rule.
The direction of magnetic field intensity H (or current I) can be represented by a small circle with a dot or cross sign depending on whether H (or I) is out of, or into the page.
9
Biot-Savart’s Law
For different current distributions:
10
2
2
2
l (line current)
4
K S (surface current) (K: surface current density)
4
J (volume current) (J: volume current density)
4
R
L
R
S
R
v
I d aH
R
d aH
R
dv aH
R
Biot-Savart’s Law
Current distributions: (a) line current, (b) surface current, (c) volume current.
Consider conductor of finite length AB, carrying current from point A to point B.
Magnetic Field of straight Conductor
11
3
z
3/22 2
2
2 2
3
Consider the contribution H at
l Rdue to l at (0,0,z): H ,
4
But l and R= a a , ,
l R a , Hence H= a4
Letting z= cot , cosec ,
cosecH
4
z
d P
I dd d
R
d dz a z so
I dzd dz
z
dz d
I d
2 2
3
1 1
2 1
sincosec 4
H= cos cos4
Ia a d
Ior a
tan /
cot
z
z
2 21+cot x=cosec x
2 1
o o
1 2
H= cos cos4
When the conductor is semi-infinite, so that point A is now at O(0,0,0)
while B is at (0,0, ), =90 , =0 :
Ia
o o
1 2
H= 4
When the conductor is of infinite length, point A is at (0,0, ) while
B is at (0,0, ) , =180 , =0 :
H= 2
A simple appr
Ia
Ia
oach to determine :
where is is a unit vector along the line current, and is a unit vector
along the perpendicular line from the li
l
l
a
a a a
a a
ne current to the field point. 12
2 1H= cos cos4
Ia
13 α1:outside, α2: inside
The conducting triangular loop in the figure carries a current of 10 A. Find H at (0,0,5) due to side 1 of the loop. 14
Example 7.1
(a) conducting triangular loop, (b) side 1 of the loop.
2 1
1 2
o
1 2
Applying H= cos cos , that is valid for any straight, 4
thin, current carrying conductor. , , and are found as follows:
2cos cos90 0, cos , =5
29
, but , and l l x
Ia
a
a a a a a
1 2 1
1
1
, Hence
H cos cos4
10 2H 0 ( )
4 (5) 29
H 59.1 mA/m
z
x z y
y
y
a a
so a a a a
Ia
a
a
15
Example 7.1 Solution
16
Example 7.2 Find H at (-3,4,0) due to the current filament shown in the figure.
(a) current filament along semi-infinite x- and z-axes, aℓ and a for H2 only; (b) determining a for H2.
1 2 1
2
2 2 1
1/2
o o
1 2
Let H=H +H at P(-3,4,0), where H is due
to current filament along x-axis, and H is due to current filament
along z-axis.
H cos cos4
At P(-3,4,0), =(9+16) 5,
=90 , =0
l
Ia
a a a
,
but ,
3 4and
5 5
3 4 4 3
5 5 5 5
l z
x y
z x y x y
a a
a a a
a a a a a a
17
Example 7.2 Solution
2
2
2
or alternatively, from figure b,
4 3sin cos
5 5
4 33Thus, H 1 0
4 (5) 5
H 38.2 28.65 mA/m
in this case is the negative of the regular of
3cylindrical coordinates: H 1 0 (
4 (5)
x y x y
x y
x y
a a a a a
a a
a a
a a
a
1
2 1
1
1 2
) 47.75 mA/m
To find H at P:
=4, 0 , cos 3 / 5, and . Hence,
3 3H 1 23.88 mA/m
4 (4) 5
Thus H=H +H 38.2 28.65 23.88 mA/m
or H= 47.75
o
l x y z
z z
x y z
a
a a a a a a
a a
a a a
a
23.88 mA/mza 18
A circular loop located at X2+y2=9, z=0 carries a direct current of 10 A along aФ. Determine H at (0,0,4) and (0,0,-4).
19
Example 7.3
(a) circular current loop, (b) flux lines due to the current loop.
3
The magnetic field intensity dH at point P(0,0,h)
contributed by current element Idl is :
l RH
4
l , R=(0,0, ) ( , ,0)
R , and
l R 0 0
z
z
I dd
R
where d d a h x y
a ha
a a a
d d
2
2
3/22 2
0
Hence,
H= 4
By symmetry, the contributions along add up to zero H 0
z
z z z
h d a d a
h
Id h d a d a dH a dH a
h
a
20
Example 7.3 - solution
2 2 2
3/2 3/22 2 2 2
0
2
3/22 2
2
3/2
2 Thus, H=
4 4
or H=
2
(a) Substituting I=10 A, =3, h=4 gives
10(3) H 0,0,4 = 0.36 A/m
2 9 16
(b) replacing by
z zz z
z
zz
I d a I adH a
h h
Ia
h
aa
h
2
- ,
l R
(z-component remains the same)
Hence, H 0,0,4 H 0,0, 4 0.36 A/m
z
z
h
d h d a d a
a
21
Example 7.3 - solution
AMPERE'S CIRCUIT LAW - MAXWELL'S EQUATION
22
Ampere's circuit law states that the line integral of the tangential component of H around a closed path is the same as the net current Ienc enclosed by the path.
enc
enc
enc
enc
In other words, the circulation of H equals ; that is,
H l= (integral form of 3rd Maxwell's equation)
Apply Stoke's theorem,
H l H S
But, J S
H J (differential
L S
S
I
d I
I d d
I d
form of third Maxwell's equation)
AMPERE'S CIRCUIT LAW - MAXWELL'S EQUATION
23
enc
2
enc enc
H l apply to Amperian path ( ).
current enclosed by amperian path.
is found if J(A/m ) is known: J S
or if K(A/m) is known for surface current density.
L
S
d L
I
I I d
encH l=d I
Consider infinite filamentary current I along the z-axis. To determine H at point P, allow Amperian path passing through P, such that H is constant provided ρ is constant.
APPLICATIONS OF AMPER'S LAW
24
A. Infinite Line Current
2
0
The whole current is enclosed by the path,
according to Amper's law:
a a
= (2 )
or H= a2
I
I H d
I H d H
I
encH l=d I
25
B. Infinite Sheet of Current
y y
enc
Consider an infinite current sheet in the z=0 plane with uniform
current desnity K= a A/m. Applying Ampere's law to the
rectangular closed 1-2-3-4-1 path gives: H l
Consid
y
K
d I K b
er the sheet as comprising of filaments
Consider H above and below the sheet due to a pair of
filamentary currents.
d
26
0
0
2 3 4 1
1 2 3 4
The resultant H has only an x-component.
H on one side is the negative of that on the other side.
0H=
0
Evaluating the line integral of H along the closed path:
H. l
x
x
d
H a z
H a z
d
enc
0 0 0 0
n n
H. l=
10( )+( )( ) 0( ) ( )=2
2
1 0
2H=
10
2
In general, for an infinite sheet of current density K A/m,
1H= K a where a is a unit normal vector dire
2
y
y y
y x
y x
d I K b
a H b a H b H b K b H K
K a z
K a z
cted from
the current sheet to the point of interest
27
Magnetic field of Infinite Sheet of Current
n
1H= K a
2
28
Infinitely Long Coaxial Transmission Line
Consider infinitely long coaxial transmission line of two concentric cylinders
The inner conductor has radius and carries current , the outer conductor has
inner radius b and thickness t and carries
a I
return current .
To determine H everywhere, apply Ampere's law in four possible regions:
0 , a , ,
I
a b b b t b t
29
Infinitely Long Coaxial Transmission Line
30
1
1
enc
2
2
2
enc 2 2
0 0
For region 0 : apply Ampere's law to path L
H l J S
Since the current is uniformly distributed over
the cross section, J= , S=
J S
L
z z
a
d I d
Ia d d d a
a
I II d d d
a a
1
2
2
2
2
2 2
2
enc 2
2 or 2
For region a : Apply Ampere's law to path L
H l (since the whole current is enclosed by L )
2 or (same as infinite straight2
L
L
I
a
I IH dl H H
a a
b
d I I
IH I H
filamentary current)
31
3
3
enc
enc 2 2
2 2 2
enc 22 20
2 2
2
For region :
Apply Ampere's law to path L
H l 2
where
J S, J=
, 12
12 2
L
z
b
b b t
d H I
II I d a
b t b
I bThus I I d d I
t btb t b
I bH
t bt
4
4For region : Apply Ampere's law to path L
H. l 0 or 0L
b t
d I I H
2
2 2
2
a 02
a aPutting all equations 2H=
together:
1 a 2 2
0
Ia
a
Ib
I bH b b t
t bt
b t
Infinitely Long Coaxial Transmission Line
32
Infinitely Long Coaxial Transmission Line
33
Planes z=0 and z=4 carry current K= -10 ax A/m and K=10 ax A/m, respectively. Determine H at (a) (1,1,1) (b) (0,-3,10)
34
Example 7.5
0 4 0 4
0 n
1 n
Let H=H +H , where H +H are
the contributions due to current
sheets z=0 and z=4,
(a) At (1,1,1) , which is between the plates (0 ( 1) 4),
H (1/ 2)K a (1/ 2)( 10a ) a 5a A/m
H (1/ 2)K a (1/ 2)(10a ) (
x z y
x
z
0 n
1 n
a ) 5a A/m
Hence, H=10a A/m
(b) At (0,-3,10) , which is above the sheets ( 10 4 0),
H (1/ 2)K a (1/ 2)( 10a ) a 5a A/m
H (1/ 2)K a (1/ 2)(10a ) a 5a A/m
Hence, H= 0 A/m
z y
y
x z y
x z y
z
35
Example 7.5
A toroid whose dimensions are shown in the figure has N turns and carries current I. Determine H inside and outside the toroid. 36
Example 7.6
37
enc
0 0
0
The net current enclosed by the Amperian path is . Hence,
H l= (2 )
or H= , for 2
where is is the mean radius of the toroid.
Outside the toroid, the current enclos
NI
d I H NI
NIa a
ed by an Amperian path is
- 0 and Hence =0NI NI H
Example 7.6
38
Magnetic Field of a Toroid
•Electric flux density and Electric field intensity are related by D=ε0 E
in free space.
•Similarly, the magnetic flux density B is related to the magnetic
field intensity H by:
•Where μ0 is known as the permeability of free space.
•The magnetic flux through a surface is given by
•Where Ψ is in webers (Wb), B is in (Wb/m2) or teslas (T).
Magnetic Flux Density
39
0B H
7
0 4 10 H/m
= B SS
d
•Magnetic flux line is a path to which B is tangential at every point on the line. •Each flux line is closed and has no beginning or end.
Magnetic Flux Lines
40
•Unlike electric flux lines, magnetic flux lines always close upon themselves. •This is because it is not possible to have isolated magnetic poles (or magnetic charges).
41
•In an electrostatic field the flux crossing a closed surface is the same as the charge enclosed.
•So it is possible to have an isolated electric charge and the flux lines produced by it need not be closed.
D SS
d Q
B S 0S
d
42
It is not possible to isolate the north and south poles of a magnet.
43
Broken Magnet
Gauss’s Law for magnetostatic fields
44
The total flux through a closed surface in a magnetic field is zero. Applying divergence theorem, Or This is the Maxwell’s fourth equation. It states that magnetostatic fields have no sources or sinks.
B S B 0S v
d dv
B S 0d
B 0
Maxwell’s Equations for Static Fields
45
*In electrostatics electric field intensity and potential are related by:
*Similar to this we can relate magnetic field intensity with two magnetic potentials: •Magnetic scalar potential (Vm) •Magnetic vector potential (A)
*Magnetic scalar potential Vm is related to H by the relation:
Magnetic Scalar and Vector Potentials
46
E V
m
2
J= H= ( ) 0 (since for any scalar, ( ) 0)
so the magnetic scalar potential V is only defined in the region where J=0.
satisfies Laplace's equation 0 (J=0)
m
m m
V V
V V
H if J=0mV
47
Since for a magnetostatic field B=0
For any vector ( A)=0
we can define A such that
B= A
In many EM problems it is more convenient to first find A and then
find B from it.
magnetic vector potential
A
0
0
0
l for line current
4
for surface current4
J for volume current
4
L
S
v
Id
R
KdSA
R
dvA
R
Magnetic Vector Potential
Magnetic flux from vector potential
48
The magnetic fluc through a given area can be found from
= B S
Applying Stoke's theorem, we obtain,
= B S ( A) S A l
A l
S
S S L
L
d
d d d
d
49
Example 7.7 Given the magnetic vector potential A=-ρ2/4 az Wb/m, calculate the total magnetic flux crossing the surface Ф=π/2, 1≤ρ≤2 m, 0≤z≤5 m.
25 2
2
10 1
Method 1
B A= a a , S= a2
Hence,
1 1 15B S= (5)
2 4 4
3.75 Wb
z
z
Ad d dz
d d dz
Example 7.7 Solution
50
1 2 3 4
1 3
5 02 2
2 4
0 5
Method 2
A l=
where is the path bounding surface .
Since A has only z-component,
0
11 (2)
4
1 15(1 4)(5) 3.75 Wb
4 4
L
d
L S
dz dz
Example 7.7 Solution Continued A=-ρ2/4 az