tan
HB
B tan^0
H 2ni
B
r
0
(^2) tan tan
i r BH K
n
i Ktan
Where K is called as T.G. constant (or) reduction
factor of T.G., r-radius of the coil in meter;
BH Horizontal component of earth’s magnetic
field in tesla;
icurrent in amperes
- Deflection Magnetometer
(I)Tan A position : In this position the
magnetometer is set perpendicular to magnetic
meridian so that, magnetic field due to magnet,
is in axial position and perpendicular to earth’s
field.
18. Magnetic Susceptibility
0
2 2 22
tan.
H 4 ( )M r
B
r l
0
3
tan.^2
H 4
B M
r
(r>>l)
(II)Tan B position : The arms of magnetometer
are set in magnetic meridian, so that the
magnetic field due to magnet is at its equatorial
position,- Relative permeability
0
Htan 4 .( 2 2 3/2)
B M
r l
0
Htan 4. 3
B M
r
(r>>l)(III) Comparison of magnetic moments :According to deflection method1 1
2 2tan
tanM
M
According to null deflection method3
1 1
2 2M d
M d
Magnetic Field Intensity (^) (H)
The force experienced by unit north pole of one
weber is called magnetic field strength or intensity
of magnetic field strength. i.e., H = F / m
SI unit : Am^1 or weber
Intensity of Magnetisation(I)
2
2M m l m
I
V A l A Where m = pole strength; M= Magnetic moment
a = area of cross-section of the magnet;
V=Volume of the magnet
SI unit : Am^1 I
HIt has no units- Magnetic permeability
i.e.,B
H It is a scalar having unit Hm^1
r0r
It has no units and dimensions- Relation between r and
As
- Deflection Magnetometer
16. Magnetic Field Intensity
- Intensity of Magnetisation(I)
- Magnetic Susceptibility
- Magnetic permeability
- Relative permeability
- Relation between and
- Curie’s Law:
0r
^ r ^1 - Curie’s Law:
It states that intensity of magnetisation (I) and
hence are inversely proportional to the absolute
temperature (T)
i.e.,C
T where C- Curie constant