A straight conductor of length 50 cm is moving with a velocity 5 m. `s^(-1)` in a magnetic field of strength 2T in a direction perpendicular to the field. What is the emf (in V) induced between the two ends of the conductor?

A straight conductor of length 10 cm is rotating in a vertical plane with one of its ends fixed. The angular velocity is 10 rad . s^(-1) . What is the value of emf (in muV ) induced between the two ends of the conductor if the horizontal component of earth's magnetic field at the place is 10^(-4)T ?

A straight conductor 0.1 m long moves in a uniform magnetic field 0.1 T. The velocity of the conductor is 15 m/s and is directed perpendicular to the field. The emf induced between the two ends of the conductor is

An electron moving with a veloctiy of 10^(7)m.s^(-1) enters a uniform magnetic field of 1 T along a direction parallel to the field. What would be its trajectory?

A long straight wire of length of length l is moving within a uniform magnetic field B With a velocity v perpendicular to the field . How much e.m.f. will induced?

Calculate the force acting on an electron moving with a velocity (3hati+3hatj)m.s^(-1) in a magnetic field of strength (2hatj+3hatk) tesla.

A conducting wire of length l is rotating with angular velocity w in a magnetic field B perpendicular to it. Prove that the induced e.m.f. at the two ends of the conducting wire is e = 1/2 Bwl^2 .

An electron is moving northwards with a velocity 10^(7)m/s in a magnetic field of 3 T directed eastwards. Calculate the instantaneous force on the electron.

A copper disc of diameter 20 cm is rotating uniformly about its horizontal axis passing through the centre with angular frequency 600 rpm. A uniform magnetic field of strength 10^(-2)T acts perpendicular to the plane of the disc. Calculate the induced emf between its centre and a point on the rim of the disc.

If the resistance of a conductor is 5 Omega and strength of current through it be 2A, find the terminal potential difference between the two ends of the conductor.

A rod of length b moves with a constant velocity v in the magnetic field of a infinitely long straight conducting wire that carries a current I as shown in the figure. The induced emf in the rod is