A long wire carrying a steady current is bent into a circular loop of one turn. The magnetic field at the center of loop is B. It is then bent into a circular coil of n turns. The magnetic field at the centre of this coil of n turns will be
(1) nB
(2)
(3) 2nB
(4)
A wire carrying current l has the shape as shown in the adjoining figure. Linear parts of the wire are very long and parallel to X-axis while the semicircular portion of radius R is lying in the Y-Z plane. Magnetic field at point O is :
1.
2.
3.
4.
An electron moving in a circular orbit of radius r makes n rotations per second. The magnetic field produced at the centre has magnitude:
A proton and an alpha particle both enter a region of uniform magnetic field B, moving at right angles to the field B. If the radius of circular orbits for both the particles is equal and the kinetic energy acquired by proton is 1 MeV, the energy acquired by the alpha particle will be
(1)4 MeV
(2) 0.5 MeV
(3) 1.5 MeV
(4) 1 MeV
Two identical long conducting wires AOB and COD are placed at right angle to each other, with one above other such that O is their common point for the two. The wires carry I1 and I2 currents, respectively. Point P is lying at distance d from 0 along a direction perpendicular to the plane containing the wires. The magnetic field at the point P will be
(1) μo/2πd(I1/I2)
(2)μo/2πd (I1+I2)
(3)μo/2πd(I12-I22)
(4)μo/2πd(I12+I22)1/2
A thin semicircular conducting ring (PQR) of radius r is falling with its plane vertical in a horizontal magnetic field B, as shown in figure. The potential difference developed across the ring when its speed is v, is
(1) zero
(2) Bvπr2/2 and P is at higher potential
(3) πrBv and R is at higher potential
(4) 2rBv and R is at higher potential
When a proton is released from rest in a room, it starts with an initial acceleration towards west. When it is projected towards north with a speed , it moves with an initial acceleration 3 towards west. The electric and magnetic fields in the room are
(1) mao/e west, 4mao/evo up
(2) mao/e west, 2mao/evo down
(3) mao/e east, 3mao/evo up
(4) mao/e east, 3mao/evo down
A current loop in a magnetic field
(1) experiences a torque whether the field is uniform or non-uniform in all orientations
(2) can be in equilibrium in one orentations.
(3) can be equilibrium in two orientations, both the wquilibriu states are unstable
(4) can be in equilibrium in two orientations, one stable while the other is unstable
Two similar coils of radius R are lying concentrically with their planes at right angles to each other. The currents flowing in them are I and 2I, respectively. The resultant magnetic field induction at the centre will be
(1)
(2)
(3)
(4)
An alternating electric field of frequency \(\nu\), is applied across the dees (radius=R) of a cyclotron that is being used to accelerate protons(mass=m). The operating magnetic field (B) used in the cyclotron and the kinetic energy (K) of the proton beam, produced by it, are given by:
1. \(\mathrm{B}=\frac{m \nu}{\mathrm{e}}\) and \(K=2 m \pi^{2} \mathrm{\nu}^{2} \mathrm{R}^{2}\)
2.\(\mathrm{B}=\frac{2\pi m \nu}{\mathrm{e}}\) and \(K=m^2 \pi \mathrm{\nu} \mathrm{R}^{2}\)
3. \(\mathrm{B}=\frac{2\pi m \nu}{\mathrm{e}}\) and \(K=2 m \pi^{2} \mathrm{\nu}^{2} \mathrm{R}^{2}\)
4. \(\mathrm{B}=\frac{m \nu}{\mathrm{e}}\) and \(K=m^2 \pi \mathrm{\nu} \mathrm{R}^{2}\)