Electric Potential: Formula, Energy, Unit

Electric potential energy is possessed by an object through two elements, the charge possessed by an object itself and the relative position of an object with respect to other electrically charged objects. The amount of work required to move an item from one place to another against an electric field determines the size of the electric potential(EP). Topics like EP are important for various entrance examinations such as the IIT JEE, therefore, having sound knowledge of these topics is crucial. Read the full blog on Electric Potential and learn about its derivation!

Almost every chemical reaction that occurs in your body is caused by electric forces. Almost all of the biochemistry is based on a knowledge of how these forces drive electrons to flow between atoms, as well as the structural and compositional changes that occur as a result of electron movement. However, the fundamental laws of electric forces are surprisingly straightforward: electrons repel other electrons, whereas protons and electrons attract one another. We’ll discuss where these forces originate, as well as the many concepts used by physicists, chemists, and biologists to better comprehend the electric force.

As per the definition, Electric potential energy is defined as the total potential energy a unit charge will possess if located at any point in outer space.

In other words, the total work done by an external agent in bringing a charge or system of charges from infinity to the original setup without undergoing any acceleration is referred to as the electric potential energy of that charge or system of charges.

It is a scalar quantity with no direction and just magnitude. It is represented by the letter V and is measured in Joules. It has the ML2T-3A-1 dimensional formula.

The energy of an item is determined by two main factors.

An electric circuit is only a method for converting energy. Chemical energy is utilized to conduct work on a positive test charge in the electrochemical cells of a battery-powered electric circuit to transport it from the low potential terminal to the high potential terminal. Within the internal circuit, chemical energy is converted to electric potential energy (i.e., the battery). After reaching the high potential terminal, a positive test charge will go via the external circuit and perform work on the light bulb, motor, or heater coils, converting the circuit’s electric potential energy into useable forms. The positive test charge returns to the negative terminal with low energy and potential, ready to start the cycle (or should we say circuit) over.

A charge in an electric field has potential energy, which is measured by the amount of work required to move the charge from infinity to that point in the electric field. The electric potential energy of the system is; (if two charges q1 and q2 are separated by a distance d):U = [1/(4πεo)] × [q1q2/d]When two similar charges (two protons or two electrons) are brought together, the system’s potential energy increases. When two opposite charges, such as a proton and an electron, are brought together, the system’s electric potential energy decreases.

Formula Method 1:

The electric potential at any place in the area of a point charge q is calculated as follows:V = k × [q/r]Where,

Formula Method 2:

Coulomb’s law states that the EP between any two arbitrary charges q1 and q2 separated by a distance r and is mathematically expressed as:U = k × [q1q2/r2]Here,

Note that the EP at infinity is 0 (as shown by r = in the formula above).

Consider a point charge ‘q’ in the presence of another charge ‘Q’ separated by an infinite distance.

UE (r) = ke × [qQ/r]

where, ke = 1/4πεo = Columb’s constant

Consider a point charge ‘q’ in the presence of numerous point charges Qi separated by an infinite distance.

UE (r) = ke q × ∑ni = 1  [Qi /ri]

Consider the following charge: q1. Let’s assume they’re separated by a distance of “r” from one another. The entire work done by an external force in moving the charge from infinity to the given point.

It can be written as, -∫ (ra→rb) F.dr = – (Ua – Ub)The point rb is at infinity, while the point ra is r, as we can see.Substituting the values we can write, -∫ (r →∞) F.dr = – (Ur – U∞)Uinfinity is equivalent to zero, as we all know.As a result, – (r) F.dr = -URUsing Coulomb’s law, we can write the following between the two charges:⇒ -∫ (r →∞) [-kqqo]/r2 dr = -URAlternatively, -k × qqo × [1/r] = URTherefore, UR = -kqqo/r

Consider a point charge ‘q’ in the presence of another charge ‘Q’ separated by an infinite distance.UE (r) = ke × [qQ/r]Here, ke = 1/4πεo = Coulomb’s constant

Consider a single point charge ‘q’ in the presence of many point charges Qi separated by an indefinite distance.UE (r) = ke q × ∑ni = 1  [Qi /ri]Electric Potential for Multiple Charges

The potential energy of a system with three charges q1, q2, and q3 at the vertices of a triangle is,U =U12 + U23 + U31 = (1/4πεo) × [q1q2/d1 + q2q3/d2 + q3q1/d3]

The electric potential energy of the system is, if four charges q1, q2, q3, and q4 are placed at the four corners of a square.U = (1/4πεo) × [(q1q2/d) + (q2q3/d) + (q3q4/d) + (q4q1/d) + (q4q2/√2d) + (q3q1/√2d)]

Special Cases:

The work done in the field of a charge Q is given by, if a charge q is moved against the electric field from a distance ‘a’ to a distance ‘b’ from Q.W = (Vb – Va) × q = [1/4πεo × (Qq/b)] – [1/4πεo × (Qq/a)] = Qq/4πεo[1/b – 1/a] = (Qq/4πεo)[(a-b)/ab]

The potential between two points (E) in an electrical circuit is defined as the amount of work (W) done by an external agent in transferring a unit charge (Q) from one point to another.

On a mathematical basis, we may state,E = W/QHere,E = the difference in electrical potential between two locations.Q = Quantity of charge in coulombs W = Work done in transferring a charge from one place to another

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The potential between two points (E) in an electrical circuit is defined as the amount of work (W) done by an external agent in moving a unit charge (Q) from one point to another. On a mathematical basis, we may state, W/Q = E

The total potential energy a unit charge will have if it is located anywhere in space is described as electric potential energy.

In this blog, we discussed Electric Potential along with its formula and the derivation. We hope the information provided was helpful. Stay connected with Leverage Edu for more educational content and amazing quizzes!