What work is required to bring a charge q =300 C originally a distance of 1.50 m from a charge Q = 20.0 `mu` C unit it is 0.50 m away ?

What work is required to bring a charge q= 3.00 mu C originally a distance of 1.50 m from a charge Q= 20.0 muC until it is 0.50 m away ?

What minimum work must be done by an external force to bring a charge q=3.00 muC from a great distance away (take t = infty ) to a point 0.500 m from a charge = 20.0 muC ?

There exists a uniform electric field E =4 xx 10^(5) Vm^(-3) directed along negative x-axis such that electric potential at origin is zero. A charge of - 200 mu C is placed at origin and a charged of + 200 mu C is placed at a (3 m, 0) . The electrostatic potential energy of the system is

An electric dipole consists of charges pm 2.0 xx 10^(8) C separated by a distance of 2.0 xx 10^(-3) m. It is placed near a long ilne charge of linear charge density 4.0 xx 10^(-4) C m^(-1) as shown in figure (30-W4), Such thet the negative charge is at a distance of 2.0 cm from the line charge. Find the force acting on the dipole.

Two identical rings P and Q of radius 0.1 m are mounted coaxially at a distance 0.5 m apart. The charges on the two rings are 2 mu C and 4 mu C , respectively. The work done in transferring a charge of 5 mu C from the center of P to that of Q is.

The work done in bringing a unit positive charge from infinite distance to a point at distance x from a positive charge Q is W. Then the potential phi at that point is

An inductor of inductance 2.0 mH s connected across a charged capacitor of capacitance 5.0 mu F and the resulting LC circuit is set oscillating at its natural frequency. Let Q denote the instantaneous charge on the capacitor and I the current in the circuit. It is found that the maximum value of charge Q is 200 mu C . a. When Q = 100 mu C , what is the value of |(dI)/(dt)| ? b. When Q = 200 mu C , what is the value of I ? c. Find the maximum value of I . d. When I is equal to one-half its maximum value, what is the value of |Q| ?

Determine the potential at a point 0.50 m (i) from a+20 muC potential charge (ii) from a-20 muC point charge.

Charges 5 muC and 10 muC are placed 1 m apart. Work done to bring these charges at a distance 0.5 m from each other is (k = 9 xx 10^(9) SI)

Four idenbtial charges +50 mu C each are placed, one at each corner of a square of side 2 m . How much external energy is required to bring another charge of +50 mu C from infinity to the centre of the square (Given (1)/(4pi epsilon_(0)) = 9 xx 10^(9)(Nm^(2))/(C^(2)))