A particle of charge `-q` and mass m moves in a circle of radius r around an infinitely long line charge of linear charge density `+lamda`. Then, time period will be
where , `k=1/4piepsilon_0)`

For an infinite line of charge having linear charge density lambda lying along x-axis the work done in moving a charge q form C to A along CA is

Find the equation of the equipotential for an infinite cylinder of radius r_(0) carrying charge of linear density lambda .

Two particles of equal mass (m) each move in a circle of radius (r) under the action of their mutual gravitational attraction find the speed of each particle.

An electron is moving around infinite linear positive charge in the orbit of 0.1 m. If the linear charge density is 1 muC//m , the velocity of electron will be

Find the force experienced by a semicircular rod having a charge q as shown in fig. Radius of the wire is R, and the line of charge with linear charge density lambda passes through its center and is perpendicular to the plane of wire.

Two particles of equal mass m move around a circle of radius R under the influence of their mutual gravitational attraction, the speed of each particle with respect to their center of mass will be ..........

A particle of mass m moves on a circular path of radius r . Its centripetal acceleration is kt^(2) , where k is a constant and t is time . Express power as function of t .

A particle of mass m is moving in a horizontal circle of radius r, under a centripetal force equal to - (K//r^(2)) . Where K is constant. What is the total energy of the particle?

Let E_1(r) , E_2(r) and E_3(r) be the respectively electric field at a distance r from a point charge Q , an infinitely long wire with constant linear charge density lambda , and an infinite plane with uniform surface charge density sigma . If E_1(r_0)=E_2(r_0)=E_3(r_0) at a given distance r_0 , then