An alpha particle is moving with velocity `vecv` in the direction of mangetic field `vec B.` Find force acting on it.

Twelve wires of equal lengths are connected in the form of a skelton cube which is moving with a velocity vecv in direction of magnetic field vecB . Find the e.m.f. in each arm of the cube.

When a charged particle moving with velocity vecv is subjected to a magnetic field of induction vecB , the force on it is non-zero. This implies that

Force on a charge in electric and magnetic fields A charge particle follows a parabolic path in a uniform electric field and a charged particel moving in a uniform magnetic field has two kinds of motions lnear motion in the direction of magnetic field and circular motion in a plane perpendicular to the magnetic field. when charge q is moving perpendicular to the magnetic field B, the radius of the circular path is r=(mv)/(Bq) . If v and B makes an angle theta , then r=(mvsintheta)/(Bq) , and the time period T=(2pim)/(Bq) . When a charged particle q is moving with velocity vecv in a magnetic field vecB , the force is non-zero. It means.

A charged particle moves with velocity vecv in a uniform magnetic field vecB . The magnetic force experienced by the particle is

Write a relation for the force vecF acting on a charge carrier q moving with velocity vecv through the magnetic field vecB in vector notation. Using this relation, deduce the conditions under which this force will be maximum?

Write a relation for the force vecF acting on a charge carrier q moving with velocity vecv through the magnetic field vecB in vector notation. Using this relation, deduce the conditions under which this force will be minimum?

If a particle of charge q is moving with velocity v along x-axis and the magnetic field B is acting along Y-axis, use the expression vecF=q(vecv xx vecB) to find the direction of force vecF acting on it.