In the figure shown magnetic field `B` is constant and uniform and in the direction perpendicular to the plane of paper. Velocity of a conducting wire `YZ` is varying with time as `V=v_(0)cosomegat`. Find the value of `omega` (in rad/sec) so thhat heat generated in circuit will be maximum (neglect friction and resistance of rails:

A wire of mass m and length l can slide freely on a pair of fixed, smooth.vertical rails (figure).A magnetic field B exists in the region in the direction perpendicular to the plane of the rails.The rails are connected at the top end by an initially unchanged capacitor of capacitance C .Find the velocity of the wire at any time (t) after released.Neglecting any electric resistance.(initial velocity of wire is zero)

A V-shaped conducting wire is moved inside a magnetic field as shown in figure. Magnetic fiel d is perpendicular to paper inwards. Then

In the figure shown a T-shaped conductor moves with constant angular velocity omega in a plane perpendicular to uniform magnetic field B. The potential difference V_A-V_B is

In the figure shown the four rods have lambda resistance per unit length . The arrangement is kept in a magnetic field of constant magnitude B and directed perpendicular to the plane of the figure and direction inwards . Initially the sides as shown form a square . Now each wire starts moving with constant velocity v towards opposite wire . Find as a function of time . Induced current in the circuit with direction

in fig. The four rods have lambda resistance per unit length. The arrengement is kept in a magnetic field of constant magnitude B and directed perpendicular to the plane of the figure and directing in ward. Initially, the sides as shown form a square. Now each wire starts moving with constant velocity v toward the opposite wire. Find as a function of time: (a) induced emf in the circuit. (b) induced current in the circuit with direction. ( c ) force required on each wire to keep its velocity consatnt. (d) total power required to maintain constant velocity. (e) thermal power developed in the circuit.

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.

In the figure shown the four rods have lambda resistance per unit length. The arrangement is kept in a magnetic filed of constant magnitude B and directed perpendicular to the plane of the figure and direction inwards. Intially the sides as shown from a square. Now each wire starts moving with constant velocity v towards opposite wire. Find as a function of time: (a) induced emf in the circuit (b) induced current in the circuit with direction

A loop of irregular shape of conducting wire PORS (as shown in figure) placed in a uniform magnetic field perpendicular to the plane of the paper changes into a circular shape. The direction of induced current will be

In the figure shown the four rods have lambda resistance per unit length . The arrangement is kept in a magnetic field of constant magnitude B and directed perpendicular to the plane of the figure and direction inwards . Initially the sides as shown form a square . Now each wire starts moving with constant velocity v towards opposite wire . Find as a function of time . Force required on each wire to keep its velocity constant .

In the figure shown as uniform magnetic field |B|=0.5T is perpendicular to the plane of circuit. The sliding rod of length l=0.25 m moves uniformly with constant speed v=4ms^-1 . If the resistance of the sllides is 2Omega , then the current flowing through the sliding rod is