Figure shows two rings having charges Q and `- sqrt(5)Q`. Find potential difference a and B i.e. `(V_(A)-V_(B))`.

Potential difference between points A and B (i.e. V_(A) - V_(B) ) is -----

Asseration: A point charge q is placed at centre of spherical cavity inside a spherical conductor as shown. Another point charge Q is placed outside the conductor as shown. Now as the point charge Q is pushed away from conductor, the potential difference (V_(A) - V_(B)) between two points A and B within the cavity of sphere remains constant. Reason: The electric field due to charges on outer surface of conductor and outside the conductor is zero at all points inside teh conductor.

In the circuit as shown,the charge varies with time t as q=t^(3)-4 ,where q is in coulombs and t is in seconds.Where at t=2 , the potential difference between A and B, V_(A)-V_(B) in volts is

In the figure shown, conducting shells A and B have charges Q and 2Q distributed uniformly over and B. Value of V_(A) - V_(B) k is (kQ)/(nR) . Find n ( k = (1)/(4 pi in_(0))

Potential difference V_(A) - V_(B) in the network shown in

Potential difference V_(B)-V_(A) in the network shown is

A charge q = + 1 muC is held at 0 between two points A and B such that AO = 2m and BO = 1m Calculate the value of potential differences (V_(A) - V_(B)) . What will be the value of potential differences (V_(A) - V_(B)) if position of B is charged as shown in Fig ?

In figure two points A and B are located in a region of electric field . The potential difference V_(B)-V_(A) is