Advertisements
Advertisements
Question
The magnetic field B and the magnetic intensity H in a material are found to be 1.6 T and 1000 A m−1, respectively. Calculate the relative permeability µr and the susceptibility χ of the material.
Advertisements
Solution
Here,
Magnetic field strength, B = 1.6 T
Magnetising intensity in a material, H = 1000 A/m
The relation between magnetic field and magnetising field is given by
\[\mu = \frac{B}{H}\]
\[ \Rightarrow \mu = \frac{1 . 6}{1000}\]
\[ \Rightarrow \mu = 1 . 6 \times {10}^{- 3}\]
Relative permeability is defined as theratio of permeability in a medium to that in vacuum.
\[\text{So, }\mu_r = \frac{\mu}{\mu_0} = \frac{1 . 6 \times {10}^{- 3}}{4\pi \times {10}^{- 7}}\]
\[ \Rightarrow \mu_r = 0 . 127 \times {10}^4 \]
\[ \Rightarrow \mu_r = 1 . 3 \times {10}^3 \]
Relative permeability `(mu_r)` is given by,
\[ \mu_r = (1 + \chi)\]
\[ \Rightarrow \chi = 1 . 3 \times {10}^3 - 1\]
\[ \Rightarrow \chi = 1300 - 1\]
\[ \Rightarrow \chi = 1299 = 1 . 299 \times {10}^3 \]
\[ \Rightarrow \chi \approx 1 . 3 \times {10}^3\]
APPEARS IN
RELATED QUESTIONS
Assume that each iron atom has a permanent magnetic moment equal to 2 Bohr magnetons (1 Bohr magneton equals 9.27 × 10−24 A m2). The density of atoms in iron is 8.52 × 1028 atoms m−3. (a) Find the maximum magnetisation I in a long cylinder of iron (b) Find the maximum magnetic field B on the axis inside the cylinder.
At a certain temperature, a ferromagnetic material becomes paramagnetic. What is this temperature called?
Answer the following question.
Define the term "Intensity" in the photon picture of electromagnetic radiation.
An iron rod is placed parallel to magnetic field of intensity 2000 A/m. The magnetic flux through the rod is 6 × 10−4 Wb and its cross-sectional area is 3cm2. The magnetic permeability of the rod in `"Wb"/("A" - "m")` is ____________.
An electron moves in a circular orbit with uniform speed v. It produces a magnetic field B at the centre of the circle. The radius of the circle is [µ0 = permeability of free space, e = electronic charge]
For an isotropic medium B, µ, H and M, are related as (where B, µ0, H and Mz have their usual meaning in the context of magnetic material) ____________.
A solenoid has core of a material with relative permeability 500 and its windings carry a current of 2 A. The number of turns of the solenoid is 500 per metre. The magnetization of the material is ______.
Coercivity of a magnet where the ferromagnet gets completely demagnetized is 6 x 103 Am-1. The minimum current required to be passed in a solenoid having 2000 turns per metre, so that the magnet gets completely demagnetized when placed inside the solenoid is ____________.
Assertion: Susceptibility is defined as the ratio of intensity of magnetisation I to magnetic intensity H.
Reason: Greater the value of susceptibility, smaller the value of intensity of magnetisation I.
What is the magnetization of a bar magnet having length 5 cm and area of cross section 2 cm2? (M = 1 Am2)
The variation of intensity of magnetization (I) and applied magnetic field intensity (H) for three magnetic materials A, B, C are shown in the graph. The material A is ____________.
Two parallel conducting wires of equal lengths placed distance 'd' apart carry currents 'I1' and 'I2' respectively in opposite directions. The resultant magnetic field at the midpoint of both the wires is ______.
(µ0 = permeability of free space.)
If `vec"H"` = magnetic intensity, `chi` = susceptibility, magnetic moment per unit volume `vec"M"` equals ______.
Magnetic permeability is maximum for ______
For a medium of permeability µ, its magnetic susceptibility x is [µ 0 = permeability of vacuum]
The relation between relative permeability (`mu_r`) and magnetic susceptibility (`chi_m`) is:______.
An iron rod is subjected to a magnetising field of 1200 Am-1 .The susceptibility of iron is 599. Find the permeability and the magnetic field produced.
