Magnetism And Matter MCQs With Answers – Part 4 (Class 12 Physics)
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Magnetism and Matter MCQs with Answers – Part 4 (Class 12 Physics)

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311. In a shielded room, a sensitive magnetic sensor reads a much smaller magnetic field than outside. The shield is most likely effective because
ⓐ. the external field has stopped forming closed field lines
ⓑ. the sensor has become non-magnetic permanently
ⓒ. a high-permeability wall carries most field lines through itself
ⓓ. the wall material has zero volume
312. Consider the following statements across magnetism and matter. Statement I: A neutral point is produced by vector cancellation of magnetic fields. Statement II: A transformer core should have a narrow hysteresis loop. Statement III: A magnetic shield works best when its material has high permeability.
ⓐ. I and III only
ⓑ. I, II and III
ⓒ. I and II only
ⓓ. II and III only
313. A material is placed in a uniform external magnetic field. Inside the material, magnetic field lines are found to be slightly less dense than in the surrounding space. The material is most likely
ⓐ. a hard permanent magnet only
ⓑ. strongly ferromagnetic
ⓒ. diamagnetic
ⓓ. a perfect paramagnet with infinite susceptibility
314. Study the field-line behaviour in different materials.
RowMaterial responseField-line behaviour inside material
PDiamagneticSlightly less dense than outside
QParamagneticSlightly more dense than outside
RFerromagneticHighly concentrated inside
SDiamagneticHighly concentrated because \(\mu_r\gg1\)
The unsupported row is
ⓐ. Row Q
ⓑ. Row P
ⓒ. Row R
ⓓ. Row S
315. A weakly magnetic solid is repelled from a region of stronger magnetic field and shows almost no change in susceptibility when its temperature changes moderately. This behaviour best matches
ⓐ. ferromagnetism below Curie temperature
ⓑ. paramagnetism obeying Curie's law
ⓒ. a saturated hard magnet only
ⓓ. diamagnetism
316. A graph of magnetisation \(M\) against magnetic intensity \(H\) for a ferromagnetic material is described below.
Starting from the unmagnetised state, \(M\) rises rapidly for small \(H\), then rises more slowly, and finally becomes nearly constant even when \(H\) is increased further.
The nearly constant part of the graph represents
ⓐ. magnetic saturation
ⓑ. zero susceptibility for all fields
ⓒ. neutral point formation
ⓓ. magnetic declination
317. In the early part of a ferromagnetic magnetisation curve, the rapid increase of \(M\) with \(H\) is mainly due to
ⓐ. disappearance of all microscopic magnetic moments
ⓑ. conversion of magnetic field into electric field
ⓒ. growth and alignment of favourable domains
ⓓ. formation of isolated magnetic monopoles
318. A ferromagnetic specimen is already close to saturation. If the applied magnetic intensity \(H\) is increased further, the magnetisation \(M\) changes only slightly because
ⓐ. most domains are already nearly aligned
ⓑ. the magnetic field inside must be zero
ⓒ. \(\chi_m\) has become negative for all ferromagnets
ⓓ. the specimen has become diamagnetic
319. Match the magnetic material with a suitable example.
Column IColumn II
P. Diamagnetic1. Aluminium
Q. Paramagnetic2. Iron
R. Ferromagnetic3. Bismuth
S. Ferromagnetic example group4. Iron, cobalt, nickel
ⓐ. P-4, Q-1, R-3, S-2
ⓑ. P-3, Q-1, R-2, S-4
ⓒ. P-1, Q-3, R-2, S-4
ⓓ. P-3, Q-2, R-1, S-4
320. A material shows a small positive slope in its \(M-H\) graph at room temperature. When temperature is increased, the slope decreases. The material is best described as
ⓐ. ferromagnetic with a wide hysteresis loop necessarily
ⓑ. paramagnetic
ⓒ. a material with \(\mu_r\lt1\)
ⓓ. diamagnetic with strong negative susceptibility
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