A bar magnet of mass 100 g, length 7.0 c...

A bar magnet of mass 100 g, length 7.0 cm, width 1.0 cm and height 0.50 cm takes `pi/2` seconds to complete an oscillation in an oscillation magnetometer placed in a horizontal magnetic field of `25 muT`. (a) Find the magnetic moment of the magnet. (b) If the magnet is put in the magnetometer with its `0.50cm` edge horizontal, what would be the time period?

Text Solution

Verified by Experts

(a) The moment of inertia of the magnet about the axis of rotation is
`l=m/12(L^(2)-b^(2))`
`=(100xx10^(-3))/12[(7xx10^(-2))^2+(1xx10^(-2))^2]kg-m=25/6xx10 kg m`
We have, `T=2pisqrt(1/(MB))`
or `M=(4pi^(2)l)/(BT^(2))=(4pi^(2)xx25xx10^(-5)kg//m^(2))/(6xx(25xx10^(-6T)xxpi^(2)/4s^(2)))=27 A-m^(2)`
(b) In this case the moment of inertia becomes
` I=m/12(L^(2)+b^(2))` where `b=0.5 cm`
The time period would be
`T=sqrt(I/(MB))`...(ii)
Dividing the equation (i),
`(T')/T=sqrt((I')/I)=sqrt(m/12(L^(2)+b^(2)))/sqrt(m/12(L^(2)+b^(2)))=sqrt((7cm)^(2)+(0.5 cm)^(2))/sqrt((7cm)^(2)+(1.0 cm)^(2))=0.992`
or `T'=(0.992xxpi)/2s=0.496pi s`.

Topper's Solved these Questions

ELECTRODYNAMICS
RESONANCE ENGLISH|Exercise PROBLEM|12 Videos
ELECTRODYNAMICS
RESONANCE ENGLISH|Exercise Exercise-1 PART-1|83 Videos
ELECTRO MAGNETIC WAVES
RESONANCE ENGLISH|Exercise Exercise 3|27 Videos
ELECTROMAGNETIC INDUCTION
RESONANCE ENGLISH|Exercise A.l.P|19 Videos

Similar Questions

Explore conceptually related problems

A bar magnet of length 5cm, width 3cm and height 2cm takes 5s to complete an oscillation in viberation magnetometer placed in a horizontal magnetic field of 20muT . The mass of this bar magnet is 250g(a). Find the magnetic moment of the magnet. (b) If the magnet is put in the magnetormer with its 0.5cm edge horizontal, what would be the new time period?

Time period of a bar magnet oscillating in earth's magnetic field is T. Its magnetic moment is M. Now, a bar magnet of magnetic moment 2M is brought near it. The new time period will be

The time period of oscillation of a bar magnet suspended horizontaliy along the magnetic meridian is T_(0) . If this magnet is replaced by another magnet of the same size and pole strength but with double the mass, the new time period will be

The needle of a deflection magnetometer deflects through 45^@ from north to south when the instrument is used in Tan-A position with a magnet of length 10cm placed at a distance of 25cm. (a) Find the magnetic moment of the magnet if the earth's horizontal magnetic field is 20 muT . (b) If the magnetometer is used in Tan-B position with the same magnet at the same separation from the needle, what will be the deflection?

A bar magnet of length 1cm and cross-sectonal area 1.0 cm^2 produces a magnetic field of 1.5 xx 10^(-4) T at a point in end-on position at a distance 15cm away from the centre. (a) Find the magnetic moment M of the magnet. (b) Find the magnetization I of the magnet. (c) Find the magnetic field B at the centre of the magnet.

The time period of a vibration magnetometer is T_(0) . Its magnet is replaced by another magnet whose moment of inertia is 3 times and magnetic moment is 1//3 of the initial magnet. The time period now will

The dipole moment of a short bar magnet is 1.25 A-m^(2) . The magnetic field on its axis at a distance of 0.5 metre from the centre of the magnet is

A uniform magnetic field of 0.20 xx 10^(-3) T exists in the space. Find the the change in the magnetic scalar potential as one moves through 50cm along the field.

A short bar magnet of magnetic moment 0*4JT^-1 is placed in a uniform magnetic field of 0*16T . The magnet is in stable equilibrium when the potencial energy is

A short magnet oscillates in a vibration magnetometer with a time period of 0.10 s where the horizontal component of earth's magnetic field is 24 mu T . An upward current of 18 A is established in the vertical wire placed 20 cm east of the magnet . Find the new time period.

RESONANCE ENGLISH-ELECTRODYNAMICS-Advanced level problems

A bar magnet of mass 100 g, length 7.0 cm, width 1.0 cm and height 0.5...
Text Solution
|
Calculate the magnetic moment (in Am^(2) ) of a thin wire with a curre...
Text Solution
|
A small charged ball having mass m and charge q is suspended from a ri...
Text Solution
|
The figure shows a conductor of weight 1.0 N& length L=0.5 m placed on...
Text Solution
|
Four long wires each carrying current I as shown in the are placed at ...
Text Solution
|
A solenoid of length 0.4m and having 500 turns of wire carries a curre...
Text Solution
|
A uniformly charged ring of radius 0.1 m rotates at a frequency of 10^...
Text Solution
|
The current density vecj inside a long, solid, cylindrica wire of radi...
Text Solution
|
A neutral particle is at rest in a uniform magnetic field B. At time t...
Text Solution
|
A non-uniform magnetic field vecB=B(0)(1+y/d)(-hatk) is present in reg...
Text Solution
|
A neutral atom of atomic mass number 100 which is stationary at the or...
Text Solution
|
In the figure shown a positively charged particle of charge q and mass...
Text Solution
|
A thin beam of charged particles in incident normally on the boundry o...
Text Solution
|
An electron moving with a velocity vecV(1)=2hatim/s at a point in a ma...
Text Solution
|
An electron is shot into one end of a solenoid.As it enters the unifor...
Text Solution
|
At time t(1), an electron is sent along the positive direction of x-ax...
Text Solution
|
In the figure shown an infinitely long wire carries a current I(1) and...
Text Solution
|
A loop PQR formed by three identical uniform conducting rods each of l...
Text Solution
|
In order to impatt an angular velocity to an earth satellite the geoma...
Text Solution
|
Given figure shows a coil bent with all edges of length 1 m and carryi...
Text Solution
|
Two particles, each having a mass m are placed at a separation d in a ...
Text Solution
|