If a current carrying loo experiences a force `bar F` = `[F_0 hat(k)]` (where `F_0` is positive constant) then nature of magnetic field should be

A magnetic field vec(B) = B_(0)hat(j) , exists in the region a ltxlt2a , and vec(B) = -B_(0) hat(j) , in the region 2a lt xlt 3a , where B_(0) is a positive constant . A positive point charge moving with a velocity vec(v) = v_(0) hat (i) , where v_(0) is a positive constant , enters the magnetic field at x= a . The trajectory of the charge in this region can be like

A current carrying conductor placed in a magnetic field experiences maximum force when angle between current and magnetic field is :

A particle of charge qgt0 is moving at speed v in the +z direction through a region of uniform magnetic field. The magnetic force on the particle vec F = F_0 (3 hat i + 4 hat j) , where F_0 is a positive constant. (a) Determine the components B_x, B_y and B_z or at least as many of the three components as is possible from the information given. (b) If it is given in addition that the magnetic field has magnitude 6F_0 / (qv) , determine the magnitude of B_z .

A particle moving along the x axis is acted upon by a single force F = F_0 e^(-kx) , where F_0 and k are constants. The particle is released from rest at x = 0. It will attain a maximum kinetic energy of :

A particle is placed at the origin and a force F=Kx is acting on it (where k is a positive constant). If U_((0))=0 , the graph of U (x) verses x will be (where U is the potential energy function.)

A particle is placed at the origin and a force F=Kx is acting on it (where k is a positive constant). If U_((0))=0 , the graph of U (x) verses x will be (where U is the potential energy function.)

When a current carrying conductor is placed in a magnetic field, it experiences a mechanical force. What should be the angle between the magnetic field and the length of the conductor so that the force experienced is : (i) Zero (ii) Maximum ?

An electron accelerated through a potential difference V passes through a uniform tranverses magnetic field and experiences a force F. If the accelerating potential is increased to 2V, the electron in the same magnetic field will experience a force:

In a region at a distance r from z-axis, magnetic field vec(B) = B_(0)rt hat(k) is present where B_(0) is constant and t is time. Then the magnetic of induced electric field at a distance r from z-axis is given by

The potential energy U for a force field vec (F) is such that U=- kxy where K is a constant . Then