Syllabus Edition

First teaching 2023

First exams 2025

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Electric Potential Energy (HL) (HL IB Physics)

Revision Note

Ann H

Author

Ann H

Expertise

Physics

Electric Potential Energy

  • In a system of two or more charges, electric potential energy is stored due to the electric forces between them
  • The electric potential energy of a system is defined as

The work done in bringing all the charges in a system to their positions from infinity

  • Electric potential energy can be positive or negative depending on the charges involved 
    • This is different to gravitational potential energy which always has a negative value
  • Electric potential energy has a positive value when:
    • the electric force is repulsive i.e. between two similar charges
    • energy is released as charges become separated
  • Electric potential energy has a negative value when:
    • the electric force is attractive i.e. between two opposite charges
    • energy must be supplied to separate the charges
  • A graph of potential energy Ep against distance r can be drawn for two like charges and two opposite charges
  • The gradient of the graph at any particular point is the value of electric force F at that point

Graph of electric potential energy against distance

electric-potential-energy-graph

The electric potential energy of two similar charges decreases with distance and increases for two opposite charges

Electric Potential Energy Equation

  • The electric potential energy of two point charges is given by:

E subscript p space equals space k fraction numerator q subscript 1 q subscript 2 over denominator r end fraction

  • Where:
    • Ep = electric potential energy (J)
    • q1, q2 = magnitudes of the charges (C)
    • r = distance between the centres of the two charges (m)
    • k = Coulomb constant (N m2 C–2)
  • Similar to electric potential, values of electric potential energy depend on the signs of q1 and q2
    • By definition, potential V = 0 at infinity, therefore Ep = 0 at infinity
  • The electric potential energy of two charges separated by a distance R can also be determined from the area under a force-distance graph
    • However, determining this area for distances between R and infinity is difficult, so it is much simpler to use the equation above

Determining area under an electric force-distance graph

4-2-8-area-under-an-electric-force-distance-graph

The area under the force-distance graph represents the electric potential energy of two similar point charges separated by R

Change in Electric Potential Energy

  • There is a change in electric potential energy when one charge moves away from another
    • This is because work must be done on the field to bring similar charges together, or to separate opposite charges
    • Conversely, work is done by the field to separate similar charges, or to bring opposite charges together
  • When a charge q2 moves away from a charge q1, the change in electric potential energy is equal to:

increment E subscript straight p space equals space k q subscript 1 q subscript 2 stretchy left parenthesis 1 over r subscript 1 space minus space 1 over r subscript 2 stretchy right parenthesis

  • Where:
    • r1 = initial separation between charges (m)
    • r2 = final separation between charges (m)

4-2-8-change-in-electric-potential-energy

There is a change in electric potential energy when a point charge moves away from another charge

  • The change in electric potential energy between two charges is analogous to the change in gravitational potential energy between two masses

Comparing gravitational and electric potential energy

comparing-potential-energies

When a small mass is lifted on Earth, there is an increase in gravitational potential energy. This is similar to the increase in electric potential energy when a negative charge moves away from a positive charge

Determining work done from a force-distance graph

  • The work done in moving a charge can also be determined from the area under a force-distance graph
  • This is equivalent to the change in electric potential energy of a moving charge

4-2-8-work-done-from-electric-force-distance-graph

The area under a force-distance graph represents the change in electric potential energy, or the work done in moving the charge

Worked example

An α-particle He presubscript 2 presuperscript 4 is moving directly towards a stationary gold nucleus Au presubscript 79 presuperscript 197

At a distance of 4.7 × 10−15 m the α-particle momentarily comes to rest. 

Calculate the electric potential energy of the particles at this instant. 

Answer: 

Step 1: Write down the known quantities

  • Distance, r = 4.7 × 10−15 m
  • Elementary charge, e = 1.60 × 1019 C
  • Coulomb constant, k = 8.99 × 109 N m2 C−2

Step 2: Determine the magnitudes of the charges

  • An alpha particle (helium nucleus) contains 2 protons
    • Charge of alpha particle, q1 = 2e
  • The gold nucleus contains 79 protons
    • So, charge of gold nucleus, q2 = 79e

Step 3: Write down the equation for electric potential energy

E subscript straight p space equals space k fraction numerator q subscript 1 q subscript 2 over denominator r end fraction

Step 4: Substitute values into the equation

E subscript straight p space equals space open parentheses 8.99 cross times 10 to the power of 9 close parentheses cross times fraction numerator 2 cross times 79 cross times stretchy left parenthesis 1.60 cross times 10 to the power of negative 19 end exponent stretchy right parenthesis squared over denominator stretchy left parenthesis 4.7 cross times 10 to the power of negative 15 end exponent stretchy right parenthesis end fraction space equals space 7.7 cross times 10 to the power of negative 12 end exponent J (2 s.f.)

Exam Tip

When calculating electric potential energy, make sure you do not square the distance!

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Ann H

Author: Ann H

Ann obtained her Maths and Physics degree from the University of Bath before completing her PGCE in Science and Maths teaching. She spent ten years teaching Maths and Physics to wonderful students from all around the world whilst living in China, Ethiopia and Nepal. Now based in beautiful Devon she is thrilled to be creating awesome Physics resources to make Physics more accessible and understandable for all students no matter their schooling or background.