Consider the situation of the previous problem. (a) Calculate the force needed to keep the sliding wire moving with a constant velocity v. (b) If the force needed just after t = 0 is `F_0`, find the time at which the force needed will be `F_0` /2.

Consider the situations of the previous proble. Let the water push the left wass by a force F_1 and the right wall byi as force F_2 .

Consider the situation of the previous problem.suppose the production of the radioactive isotope starts at t=0. Find the number of active nuclei at time t.

Consider the situation of the previous question from a frame moving with a speed v_0 parallel to the initial velocity of the block? b. What is the work done by the kinetic friction?

Consider a situation similar to that of the previous problem except that the ends of the rod slide on a pair of thick metallic rails laid parallel to the wire. At one end the rails are connected by resistor of resistance R. (a) what force is needed ot keep the rod sliding at a constant speed v? (b) in this situation what is the current in the resistance R? (c) Find the rate of heat developed in the resistor. (d) find the power delivered by the external agent exerting the force on the rod.

Consider the situation of the previous problem. A charge of 2.0xx 10 ^(-4) C is moved from the point A to the point B. find the change in electrical potential energy U_B-U_A for the cases (a) , (b) and ( c ).

A rectangular box lies on a rough inclined surface. The coefficient of friction between the surface and the box is mu . Let the mass of the box be m. (a) At what angle of inclination theta of the plane to the horizontal will the box just start to slide down the plane? (b) What is the force acting on the box down the plane, if the angle of inclination of the plane is increased to a gt theta . (c) What is the force needed to be applied upwards along the plane to make the box either remain stationary or just move up with uniform speed? (d) What is the force needed to be applied upwards along the plane to mu_k kgf make the box move up the plane with acceleration a?

Suppose the second charge in the previous problem is -1.0 xx 10^(-6) C. Locate the position where a third charge will not experience a net force.

A conducting wire ab of length l, resistance r and mass m starts sliding at t = 0 down a smooth, vertical, thick pair of connected rails as shown in . A uniform magnetic field B exists in the space in a diraction perpendicular to the plane of the rails. (a) Write the induced emf in the loop at an instant t when the speed of the wire is v. (b) what would be the magnitude and direction of the induced current in the wire? (c) Find the downward acceleration of the wire at this instant. (d) After sufficient time, the wire starts moving with a constant velocity. Find this velocity v_m. (e) Find the velocity of the wire as a function of time. (f) Find the displacement of the wire as a functong of time. (g) Show that the rate of heat developed inte wire is equal to the rate at which the gravitational potential energy is decreased after steady state is reached.

Calculate the viscous force on a ball of radius Imm moving through a liquid of viscosity 0.2 Nsm^(-2) at a speed of 0.07 ms^(-1) .

The rectangualr wire- frame, shown in has a width d, mass m, resistance R and a large length. A uniform magnetic field B exists to the left of the frame. A constant force F starts pushing the frame into the magnetic field at t =0. (a) Find the acceleration of the frame when its speed has increased to v. (b) Show that after some time the frame will move with a constant velocity till the whole frame enters into the magnetic field. find this velocity v_0 . (c) show that the velocity at tiem t is given by v= v_0(1 - e^(-Ft/mv_0) .