Electric Potential

Definition and Concept

Electric potential (V): scalar quantity representing electric potential energy per unit positive charge at a point in an electric field. Indicates work done by external force to bring a unit positive charge from infinity to that point.

Scalar Nature

Unlike electric field (vector), electric potential is scalar. Simplifies analysis of electrostatic systems. Superposition applies by algebraic addition.

Reference Point

Common reference: potential zero at infinity. Potential defined relative to this baseline. Alternative references possible depending on problem context.

Electric Potential Energy

Definition

Electric potential energy (U): energy stored by a charge due to its position in an electric field. Depends on charge magnitude and electric potential at location.

Relationship to Potential

U = qV, where q = charge, V = electric potential. Energy units: joules (J). Potential energy varies with position in field.

Work and Energy Transfer

Work done in moving charge against electric field stored as potential energy. Conservative force field: path-independent work.

Voltage and Potential Difference

Definition of Voltage

Voltage: potential difference between two points. Indicates energy per unit charge transferred between points.

Measurement

Measured in volts (V). 1 volt = 1 joule/coulomb. Positive voltage implies energy gain by positive charge moving from lower to higher potential.

Significance in Circuits

Drives current flow. Voltage sources provide potential difference. Load devices consume energy delivered by voltage.

Relation to Electric Field

Gradient Relation

Electric field (E) is negative gradient of electric potential:

E = -∇V

Direction: points from higher to lower potential.

Work Calculation

Work done by electric field moving charge q over displacement ds: dW = qE·ds = -q dV.

Field Lines and Potential

Electric field lines perpendicular to equipotential surfaces. Field strength proportional to potential gradient magnitude.

Equipotential Surfaces

Definition

Surfaces where electric potential is constant everywhere. No work done moving charge along these surfaces.

Properties

Electric field perpendicular to equipotentials. Equipotentials never intersect. Spacing indicates field strength.

Examples

Point charge: concentric spheres. Uniform field: planes perpendicular to field direction.

Calculation of Electric Potential

Point Charge

Potential at distance r from point charge q:

V = k * q / r

where k = 1/(4πε₀).

Multiple Charges

Potential due to system: algebraic sum of potentials from individual charges (superposition).

Continuous Charge Distributions

Integration over charge density ρ:

V = (1/4πε₀) ∫ (dq / r)

where r = distance from dq to field point.

Units and Dimensions

SI Unit

Volt (V): SI derived unit for electric potential. 1 V = 1 joule/coulomb (J/C).

Dimension

Dimensionally: ML²T⁻³I⁻¹ (mass, length, time, current).

Other Units

Electron volt (eV): unit of energy, not potential. 1 eV = energy gained by electron through 1 V potential difference.

Electric Potential in Circuits

Potential at Nodes

Electric potential defined at circuit nodes relative to ground. Determines current direction and magnitude.

Voltage Sources

Devices maintaining fixed potential difference. Batteries and generators are common examples.

Potential Drops

Resistors, capacitors, and other components cause potential changes. Sum of voltage rises and drops equals zero (Kirchhoff’s Voltage Law).

Applications

Electrostatics

Calculating forces, energy storage, and field distribution in charged systems.

Capacitors

Potential difference stores energy in electric field between plates.

Electric Power Systems

Voltage management for efficient energy transmission and distribution.

Common Formulas

Potential due to Point Charge

V = (1/4πε₀) * (q / r)

Potential Difference

ΔV = V_b - V_a = W_ab / q

Relation to Electric Field

E = -∇V

Quantity	Formula	Units
Electric Potential (V)	V = kq/r	Volt (V)
Potential Difference (ΔV)	ΔV = W/q	Volt (V)
Electric Field (E)	E = -∇V	Volt/meter (V/m)

Experimental Measurements

Voltmeter Usage

Measures potential difference between two points. High input impedance to avoid circuit disturbance.

Electrostatic Voltmeters

Measure absolute potential without current flow. Suitable for high-voltage or static charge measurements.

Potential Mapping

Equipotential lines mapped using probes in conductive media. Used in research and teaching labs.

Historical Development

Early Concepts

Volta’s invention of battery (1800) introduced controlled voltage sources. Concept of potential evolved from electrostatics studies.

Mathematical Formalism

Gauss and others formalized potentials using calculus. Development of scalar potential concept simplified electromagnetism.

Modern Usage

Electric potential central in circuit theory, electrostatics, and quantum mechanics. Continues to underpin electrical engineering and physics.

References

Griffiths, D.J., Introduction to Electrodynamics, 4th ed., Pearson, 2013, pp. 45-102.
Jackson, J.D., Classical Electrodynamics, 3rd ed., Wiley, 1998, pp. 12-56.
Halliday, D., Resnick, R., Walker, J., Fundamentals of Physics, 10th ed., Wiley, 2013, pp. 622-660.
Purcell, E.M., Morin, D.J., Electricity and Magnetism, 3rd ed., Cambridge University Press, 2013, pp. 85-130.
Tipler, P.A., Mosca, G., Physics for Scientists and Engineers, 6th ed., W.H. Freeman, 2007, pp. 483-530.