If linear charge density of a wire as shown in the figure is `lambda`

An infinitely long line of linear charge density lambda is shown in the figure. The potential difference V_(A)-V_(B) between the two points A and B is

A nonconducting ring of uniform mass m, radius b and uniform linear charge density lambda is suspended as shown in figure in a gravity free space. There is uniform coaxial magnetic field B_0 , pointing up in a circular region of radius 'a' (lt b) . Now if this field is switched off, then:-

An infinte wire having linear charge density lambda is arranged as shown in fig. A charge particle of mass m and charge q is released charged q is released from point P. Find the initial acceleration of the particle just after the particle is released.

Two semicircular rings lying in same plane, of uniform linear charge density lambda have radius r and 2r. They are joined using two straight uniformly charged wires of linear charge density lambda and length r as shown in figure. The magnitude of electric field at common centre of semi circular rings is -

Two semicircular rings lying in same plane, of uniform linear charge density lambda have radius r and 2r. They are joined using two straight uniformly charged wires of linear charge density lambda and length r as shown in figure. The magnitude of electric field at common centre of semi circular rings is -

A tiny electric dipole of dipole moment p is palced at a distance r from an infinitely long wire, with its vecp normal to the wire. If the linear charge density of the wire is lambda , the electrostatic force acting on the dipole is equal to

A very long uniformly charged wire oriented along the axis of a circular ring of radius R rests on its centre with one of the ends (as shown in figure). The linear charge density on the wire is lambda . Evalute the flux of the vector vecE across the circle area.

The linear charge density on a ring of radius R is lambda=lambda_0 sin (theta) where lambda_0 is a constant and theta is angle of radius vector of any point on the ring with x-axis. The electric potential at centre of ring is

A thin wire of linear charge density lambda is bent in the form of a triangle ABC and an imaginary cube of side .a. is taken with vertex A at the centre of the top face and vertices B,C at the opposite edge centres of the bottom face. The total electric flux linked with the cube is

The linear mass density , i.e mass per unit length of the rope as shown in figure , varies 0 to lambda from one end to another . The acceleration of the combined system of figure will be