Question

A charged particle (charge $$q$$ ) is moving in a circle of radius $$R$$ with uniform speed $$v.$$ The associated magnetic moment $$\mu $$ is given by

A. $$\frac{{qvR}}{2}$$  
B. $$qv{R^2}$$
C. $$\frac{{qv{R^2}}}{2}$$
D. $$qvR$$
Answer :   $$\frac{{qvR}}{2}$$
Solution :
As revolving charge is equivalent to a current, so $$ = qf = q \times \frac{\omega }{{2\pi }}$$
But $$\omega = \frac{v}{R}$$
where, $$R$$ is radius of circle and $$v$$ is uniform speed of charged particle.
Therefore, $$i = \frac{{qv}}{{2\pi R}}$$
Now, magnetic moment associated with charged particle is given by
$$\mu = iA = i \times \pi {R^2}\,\,{\text{or}}\,\,\mu = \frac{{qv}}{{2\pi R}} \times \pi {R^2} = \frac{1}{2}qvR$$
Alternative
Current produced due to circular motion of charge $$q$$ is given by
$$i = \frac{q}{T}\,\,\left[ {T = {\text{Time period}}\,{\text{of revolution}}} \right]$$
Now, $$T = \frac{{2\pi R}}{v}$$
So, $$i = \frac{q}{{2\pi R}} \times v$$
Now, magnetic moment $$\left( \mu \right)$$ is given by
$$\mu = iA$$
So, $$\mu = \frac{{qv}}{{2\pi R}} \times \pi {R^2}$$
$$ \Rightarrow \mu = \frac{{qvR}}{2}$$

Releted MCQ Question on
Electrostatics and Magnetism >> Magnetic Effect of Current

Releted Question 1

A conducting circular loop of radius $$r$$ carries a constant current $$i.$$ It is placed in a uniform magnetic field $${{\vec B}_0}$$ such that $${{\vec B}_0}$$ is perpendicular to the plane of the loop. The magnetic force acting on the loop is

A. $$ir\,{B_0}$$
B. $$2\pi \,ir\,{B_0}$$
C. zero
D. $$\pi \,ir\,{B_0}$$
View Answer
Releted Question 2

A battery is connected between two points $$A$$ and $$B$$ on the circumference of a uniform conducting ring of radius $$r$$ and resistance $$R.$$ One of the arcs $$AB$$  of the ring subtends an angle $$\theta $$ at the centre. The value of the magnetic induction at the centre due to the current in the ring is

A. proportional to $$2\left( {{{180}^ \circ } - \theta } \right)$$
B. inversely proportional to $$r$$
C. zero, only if $$\theta = {180^ \circ }$$
D. zero for all values of $$\theta $$
View Answer
Releted Question 3

A proton, a deuteron and an $$\alpha - $$ particle having the same kinetic energy are moving in circular trajectories in a constant magnetic field. If $${r_p},{r_d},$$  and $${r_\alpha }$$ denote respectively the radii of the trajectories of these particles, then

A. $${r_\alpha } = {r_p} < {r_d}$$
B. $${r_\alpha } > {r_d} > {r_p}$$
C. $${r_\alpha } = {r_d} > {r_p}$$
D. $${r_p} = {r_d} = {r_\alpha }$$
View Answer
Releted Question 4

A circular loop of radius $$R,$$ carrying current $$I,$$ lies in $$x - y$$  plane with its centre at origin. The total magnetic flux through $$x - y$$  plane is

A. directly proportional to $$I$$
B. directly proportional to $$R$$
C. inversely proportional to $$R$$
D. zero
View Answer

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Magnetic Effect of Current

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