A uniform electric field E exists between two oppositely charged plates (Fig. 3.38). What will be the work done in moving a charge q along a closed rectangular path ?
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The work done to move a charge along an equipotential from A to B

The work done to move a charge along an equipotential from A to B

The work done to move a unit charge along an equipotential from P to Q

A uniform electric field E is created between two parallel ., charged plates as shown in figure . An electron . enters the field symmetrically between the plates with a . speed v_(0)'. The length of each plate is l. Find the angle of . deviation of the path of the electron as it comes out . of the field.

A uniform electric field E is created between two parallel ., charged plates as shown in figure . An electron . enters the field symmetrically between the plataes with a . speed v_0. The length of each plate is l. Find the angle of . deviation of the path of the electron as it comes out . of the field.

The work done in moving an electric charge q in an electric field does not depend upon

For an infinite line of charge having linear charge density lambda lying along x-axis the work done in moving a charge q form C to A along CA is

a. A circle is drawn with center as a charge +q. What is the work done in moving a charge +q from B to C along the circumferebce of the circle ? B In the above question, if the charge +q is first taken from B to A and then from A to C, on which path is the magnitude of work greater?

Assertion : In a uniform electric field electrons move in the opposite direction of electric field. Reason : This is because of the negative charge of an electron.

Charges +q and -q are placed at points A and B respectively which are a distance 2L apart, C is the midpoint between A and B . The work done in moving a charge +Q along the semicircle CRD is