Two charges `Q_1 and Q_2` Coulombs are shown in fig. A third charge `Q_3 `coulomb is moved from point R to S along a circular path with P as centre. Change in potential energy is

Two charges q_(1) and q_(2) are placed 30 cm apart, as shown in the figure. A third charge q_(3) is moved along the arc of a circle of radius 40 cm from C to D . The change in the potential energy o fthe system is (q_(3))/(4pi epsilon_(0))k ., where k is

Two charges q_(1) and q_(2) are placed 30 cm apart, as shown in the figure. A third charge q_(3) is moved along the arc of a circle of radius 40 cm from C to D . The change in the potential energy o fthe system is (q_(3))/(4pi epsilon_(0))k ., where k is

A positive charge .Q. is fixed at a point, A negatively charged of mass .m. and charge .q. is revolving in a circular path of radius radius r_(1) with .Q. as the centre. The change in potential energy to change the radius of the circular path from r_(1) and r_(2) in joule is

Two identical thin ring, each of radius R meters, are coaxially placed a distance R metres apart. If Q_1 coulomb, and Q_2 coulomb, are repectively the charges uniformly spread on the two rings, the work done in moving a charge q from the centre of one ring to that of the other is

Two identical thin ring, each of radius R meters, are coaxially placed a distance R metres apart. If Q_1 coulomb, and Q_2 coulomb, are repectively the charges uniformly spread on the two rings, the work done in moving a charge q from the centre of one ring to that of the other is

Assertion: Two charges -q each are fixed points A and B. When a third chrge -q is moves from A to B, electrical potential energy first decreases than increases, Reason: Along the line joining A and B, third charge is stable equilibrium position at centre.

A point charge +q is placed at origin O . The work done in taking another point charge -q from the point A to point B along the circular arc as shown in the figure is .

A point charge q_1 = 4.00 nC is placed at the origin, and a second point charge q_2 = -3.00 nC , placed on the x-axis at x = + 20.0 cm. A third point charge q_3 = 2.00 nC is placed on the X-axis between q_1, and q_2 . (Take as zero the potential energy of the three charges when they are infinitely far apart). (a) What is the potential energy of the system of the three charges if q_3 is placed at x= + 10.0 cm? (b) Where should q_3 be placed to make the potential energy of the system equal to zero?

A two point charges 4q and -q are fixed on the x - axis x=-d/2 and x = d/2 , respectively. If a third point charge 'q' is taken from the origin to x = d along the semicircle as shown in the figure, the energy of the charge will

A positive charge Q is uniformly distributed along a circular ring of radius R .a small test charge q is placed at the centre of the ring.