In the arrangement shown in the figure, uniform magnetic field B is upward to the plane of paper. Connecter AB is smooth and conducting, gaving mass m and length l. Initially spring has extension `X_(0)`. Spring in non-coducting (neglect induction in spring). Connector is released at t=0. Maximum charge on the capacitor is

Two parallel long smooth conducting rails separated by a distance l are connected by a movable conducting connector of mass m . Terminals of the rails are connected by the resistor R and the capacitor C as shown in figure. A uniform magnetic field B perpendicular to the plane of the rail is switched on. The connector is dragged by a constant force F . Find the speed of the connector as a function of time if the force F is applied at t = 0 . Also find the terminal velocity of the connector.

In the network shown, the connector of mass m, length l and negligible resistance can smoothly side along two fixed parallel rails. The capacitor is initially uncharged and ET a uniform magnetic field B exists in the region directed into the plane of paper. If the switch S is closed at t=0 then the charge on the capacitor after long time is

A spring is connected with plank and other end of spring is connected with a block of mass m . initially spring is stretched by a distance x_(0) and block is connected with a thread which is connected to other end of the plank as shown. If thread is cut, what will be maximum speed of the plank.

A block of mass m is attached with a spring in vertical plane as shown in the figure. If initially spring is in its natural length and the block is released from rest, then maximum extension in the spring will be

Four identical conducting plates are placed parallel to each other at equal separations as shown below: Plates A and D are fixed while B and C are connected with the help of a conducting spring of spring constant k. Initially, the spring is in relaxed position and B and C are at rest, now the spring is compressed slightly by displacing B and C and then plates B and C are released to perform SHM. Now the capacitance of the system across PQ [ Mass of each plate is m]

A rectangular frame of wire is placed in a uniform magnetic field directed outwards , normal to the paper . AB is connected to a spring which is stretched to A'B' and then released at time t=0. Explain qualitatively how induced e. m .f in the coil would very with time . (Neglect damping of oscillations of spring).

A spring of spring constant 'K' is fixed at one end has a small block of mass m and charge q is attached at the other end. The block rests over a smooth horizontal surface. A uniform and constant magnetic field B exists normal to the plane of paper as shown in figure. An electric field vec(E) = E_(0) hat (i)(E_(0) is a positive constant) is switched on at t =0 sec. The block moves on horizontal surface without ever lifting off the surface. Then the normal reaction acting on the block is :

A conducting rod of length L=0.1 m is moving with a uniform sped v=0.2m//s on conducting raisli a magnetic field B=0.5T as shown. On one side, the end of the rails is connected to a capacitor of capacitance C=20muF . Then, the charge on the capacitor's plates are

A uniform thin cylindrical disk of mass M and radius R is attaached to two identical massless springs of spring constatn k which are fixed to the wall as shown in the figure. The springs are attached to the axle of the disk symmetrically on either side at a distance d from its centre. The axle is massless and both the springs and the axle are in horizontal plane. the unstretched length of each spring is L. The disk is initially at its equilibrium position with its centre of mass (CM) at a distance L from the wall. The disk rolls without slipping with velocity vecV_0 = vacV_0hati. The coefficinet of friction is mu. The maximum value of V_0 for whic the disk will roll without slipping is-

In the figure shown PQRS is a fixed resistanceless conducting frame in a uniform and constant magnetic field of strength B . A rod EF of mass m length l and resistance R can smoothly move on this frame.A capacitor charged to a potential difference V_(0) initially is connected as shown in the figure.Find the velocity of the rod as function of time t if it is released at t=0 from rest.