In the previous problem, the maximum range of movement of the centre of the part of the circle from line AD in which charged particle of charge Q moves with a velocity v when `(theta)` is positive to when `(theta)` is negative is given by

In the previous problem, if time period, T =2(pi) m/(BQ) where Q is the charge of the particle and m is its mass, the ratio of time spent by the particle in field when (theta) is positive to when (theta) is negative is given by

What is the direction of the force acting on a charged particle q, moving with a velocity vec(v) a uniform magnetic field vec(B) ?

A positive charged particle when moves from higher potential to lower potential

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

To the right of line PQ is a uniform magnetic field vec(B).B_(1)A is the line of incidence of a charged particle, which comes out of the field along DE, CA and DF are the normals at A and D. -B_(1)AC =(theta) . Angle measured from CA in clockwise direction is taken as positive. What will be the value of (theta) so that angle subtended by the part of the circle (along which charged particle moves in the field) at its centre and facing the circle is less than pi ?

When a charged particle moves in an elecltric or a magnetic field, its speed is v and acceleration is a

Two fixed insulating rings A and B carry ahanges with uniform linear aharge density +lambda and -lambda , respectively, as shown in the adjacent figure. The planes of the rings are parallel to each other and their axes are coinciding. A particle of change "q" and mass "m" is released with zero velocity from centre P of the positively charged ring. The kinetic energy of the particle when it reaches centre Q of the negatively charge ring will be

A particle of charge q is projected from point P with velocity v as shown. Choose the correct statement from the following.

The change in the kinetic energy of a charged particle moving in a uniform magnetic field will be zero when its velocity is

Write the expression for the de-Broglie wavelength associated with a charged particle having charge 'q' and mass 'm' when it is accelerated by a potential V.