In uniform electric field, `E = 10 NC^(-1)` as shown in figure, find

(i) `V_(A)-V_(B)`
(ii) `V_(B)-V_(C)`.

In the uniform electric field shown in figure, find : a. V_A-V_D b. V_A-V_C c. V_B-V_D d. V_C-V_D

In uniform electric field E=10 N//C , find a. V_A-V_B , b. VB-V_C

An unchanged conductor of inner radius R_(1) and outer radius R_(2) contains a point charge q placed at point P (not at the centre) as shown in figure? Find out the following: (i) V_(C) (ii) V_(A) (iii) V_(B) (iv) E_(A) (v) E_(B) (vi) force on charge Q if it is placed at B

A rod of length 3l rotated with an angular velocity omega as shown in figure. The unfiorm magnetic field B is into the paper. Find (a) V_(A)-V_(C) (b) V_(A) - V_(D)

Find the equivalent resistance of the network shown in the figure between the points A and B if (i) V_(A) gt V_(B) (ii) V_(A) lt V_(B)

A hollow conducting sphere is placed in an electric field produced by a point charge placed at P as shown in figure. Let V_(A), V_(B), V_(C ) be the potentials at points A, B and C respectively. Then

A hollow conducting sphere is placed in an electric field produced by a point charge placed at P as shown in figure. Let V_(A), V_(B), V_(C ) be the potentials at points A, B and C respectively. Then

A hollow conducting sphere is placed in an electric field produced by a point charge placed at P as shown in figure. Let V_(A), V_(B), V_(C ) be the potentials at points A, B and C respectively. Then

A non-conducting wire is bent into a semi-circle of radius R and a charge +Q is uniformly distributed over it as shown in the figure. Find the ratio ((V_(A))/(E_(A))) of the potential (V_(A)) to the magnitude of the electric field (E_(A)) , both evaluated at the other end A of diameter AB that bisects the wire (as shown in the figure)

A uniform electric field is along x-axis. The potential difference V_(A)-V_(B)=10 V is between two points A (2m, 3m) and (4m, 8m). Find the electric field intensity.