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

The work done in carrying a charge of 5 mu C form a point A to a point B in an electric field is 10mJ . The potential difference (V_(B) - V_(A)) is then

The work done in carrying an electron from point A to a point B in an electric is 10 MJ. The potential difference (V_(B)-V_(A)) is then

Two capacitors C_(1) and C_(2) are connected in a circuit as shown in figure. The potential difference (V_(A) - V_(B)) is

Debroglie wavelength of proton accelerated by an electric field at a potential difference v is

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

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

Figure shown three points A, B and C in a region of unifrom electric field vecE . The line AB is perpendicular and BC is parallel to the field lines. Then which of the following holds good. Where V_(A), V_(B) and V_(C) represenet the electric potential at points A, B and C respectively

Point A is located 0.25 m away from a charge of -2.1 xx 10^(-9) C . Point B is located 0.50 m away from the charge. What is the electric potential difference V_(B)- V_(A) between these two points ?

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 ?

15 joule of work has to be done against an existing electric field to take a charge of 0.01 C from A to B. Then the potential difference (V_(B) - V_(A)) is :-