A conducting rod is moved with a constant velocity v in a magnetic field. A potential difference appears across the two ends

A rod AB moves with a uniform velocity v in a uniform magnetic field as shown in figure

A copper wire bent in the shape of a semicircle of radius r translates in its plane with a constant velocity v. A uniform magnetic field B exists in the direction perpendicular to the plane of the wire. Find the emf induced between the ends of the wire if (a) the velocity is perpendicular ot the diameter joining free ends, (b) the velocity is parallel to this diameter.

A rectangular, a square, a circular and an elliptica loop, all in the (x -y) plane, are moving out of a uniform magnetic field with a constant velocity, vecV = vhat i The magnetic field is directed along the negative z axis direction. The induced emf. during the passage of these loops, out of the field region, will not reman constant for:

A conducting circular loop of radius r is rotated about its diameter at a constant angular velocity omega in a magnetic field B perpendicular to the axis of rotation. In what position of the loop is the induced emf zero?

Why should the object be moved at constant velocity when we define potential energy ?

A point charge of 2 C experiences a constant force of 1000 N when moved between two points separated by a distance of 2 cm in a uniform electric field. The potential difference between the two points is

shows a straight, long wire carrying a current I and a rod of length l coplanar with the wire and perpendicular to it. The rod moves with a constant velocity v in a direction parallel to the wire. The distance of the wire from the centre of the rod is x. Find the motional emf induced in the rod.

Shows a wire sliding on two parallel, conducting rails placed at a separation l. A magnetic feld B exists in a direction perpendicular to the plane of the rails. What force is necessary to keep the wire moving at a constant velocity v ?