In magnetic field `B=(2hati+3hatj)` T, velocity of a charged particle is given in table-1. Corresponding magnetic force is given in table-2. Match the two tables.

Magnetic field exists in a space and given as B=-(B_(0))/(a)yhatK , where B_(0) and a are constants. A wire PQ, having current I lies inside the magnetic field. If co-ordinates of P and Q are as given, then find the force acting on the wire as given in Table-2. Match the two Table.

A charged particle is moved along a magnetic field line. The magnetic force on the particle is

A charged particle moves in a uniform magnetic field B=(2hati-3hatj) T

A charged particle is moving on circular path with velocityv in a uniform magnetic field B, if the velocity of the charged particle is doubled and strength of magnetic field is halved, then radius becomes

A charged particle is moving in a circular path in uniform magnetic field. Match the following.

In magnetic field, for a charged particle (in motion) match the following table

Find out the correct match from given table :

Statement 1: A magnetic field independent of time can change the velocity of a charged particle. Statement 2: It is not possible to change the velocity of a particle in a magnetic field as magnetic field does no work on the charged particle.

A particle of mass m and charge q is in a electric and magnetic field given by vecE = 2hati + 3hatj , vecB = 4hatj +6hatk The charged particle is shifted form the origin to the point P(x = 1, y=1) along a striaght path. The magnitude of the total work done is :

If the acceleration and velocity of a charged particle moving in a constnt magnetic region is given by a=a_1hati+a_2hatk, v=b_1hati+b_2hatk.[a_1,a_2,b_1 and b_2 are constant]. Then choose the wrong statement