To review the concept of conservative forces and to understand that electrostatic forces are, in fact, conservative.
As you may recall from mechanics, some forces have a very special property, namely, that the work done on an object does not depend on the object's trajectory; rather, it depends only on the initial and the final positions of the object.

Such forces are called conservative forces. If only conservative forces act within a closed system, the total amount of mechanical energy is conserved within the system (hence the term "conservative"). Such forces have a number of properties that simplify the solution of many problems.
You may also recall that a potential energy function can be defined with respect to a conservative force. This property of conservative forces will be of particular interest of us.

Not all forces that we deal with are conservative, of course. For instance, the amount of work done by a frictional force very much depends on the object's trajectory. Friction, therefore, is not a conservative force. In contrast, the gravitational force is the most common example of a conservative force. What about electrostatic (Coulomb) forces? Are they conservative, and is there a potential energy function associated with them?
In this problem, you will be asked to use the given diagram(Figure 1) to calculate the work done by the electric field E⃗ on a particle of charge q and see for yourself whether that work appears to be trajectory-independent. Recall that the force acting on a charged particle in an electric field is given by F⃗ =E⃗ q

.
Recall that the work W done on an object by a constant force is

W=Fdcosθ

,
where F is the magnitude of the force acting on the object, d is the magnitude of the displacement that the object undergoes, and θ is the angle between the vectors F⃗ and d⃗ .

Consider a uniform electric field E⃗
and a rectangle ABCD, as shown in the figure. Sides AB and CD are parallel to E⃗ and have length L; let α be angle BAC.

A) Calculate the work WAB done by the electrostatic force on a particle of charge q as it moves from A to B.
B) Calculate the work WBC
done by the electrostatic force on the charged particle as it moves from B to C.
C) Calculate the total amount of work WABC
done by the electrostatic force on the charged particle as it moves from A to B to C.



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