Consider a uniform magnetic field `B` perpendicular to the plane. The conducting rod moves towards right with a constant velocity `v` as shown in the figure. When the rod is at a distance `x=R/2` from the centre the current through the capacitor takes the value `(2BCv^(2))/(sqrt(nR))`. Find `'n'`

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

A wire is bent in the form of a V shape and placed in a horizontal plane.There exists a uniform magnetic field B perpendicular to the plane of the wire. A uniform conducting rod starts sliding over the V shaped wire with a constant speed v as shown in the figure. If the wire no resistance, the current in rod wil

AB is a resistanceless conducting rod which forms a diameter of a conducting ring of radius r rotating in a uniform magnetic field B as shown in figure. The resistance R_(1) and R_(2) do not rotate. Then the current through the resistor R_(1) is

AB is a resistanceless conducting rod which forms a diameter of a conducting ring of radius r rotating in a uniform magnetic field B as shown in figure. The resistance R_(1) and R_(2) do not rotate. Then the current through the resistor R_(1) is

A small conducting rod of length l, moves with a uniform velocity v in a uniform magnetic field B as shown in fig __

If a charge q is moving towards the centre of an earthed conducting sphere of radius R with a velocity sqrt(2)aR m/s. Where a is positive constant. If current flowing in the ammeter shown in figure when q is at a distance aR sqrt(2) from centre of sphere. Is (q)/(asqrt(x)) find x.

A semicircular conducting wire of radius a is moving perpendicular to a uniform magnetic field B with speed √2 v as shown in the figure.The emf induced across the wire Is

A conducting wire of length l is placed on a rough horizontal surface, where a uniform horizontal magnetic field B perpendicular to the length of the wire exists. Least values of the forces required to move the rod when a current I is established in the rod are observed to be F_1 and F_2 (lt F_1) for the two possible directions of the current through the rod, respectively. Find the weight of the rod and the coefficient of friction between the rod and the surface.

A conducting rod of length l is rotating with constant angular velocity omega about point O in a uniform magnetic field B as shown in the figure . What is the emf induced between ends P and Q ?

Consider the plane of the paper to be vertical plane with direction of 'g' as shown in the figure. A rod (MM') of mass 'M' and carrying a current I . The rod is suspended vertically through two insulated spring of spring constant K at two ends. A uniform magnetic field is applied perpendicular to the plane of the paper such that the potential energy stored in the spring, in equilibrium position is zero. If the rod is slightly displaced in the vertically direction from the position of equilibrium, then the time period of oscillation is