Syllabus Edition

First teaching 2023

First exams 2025

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Electric Equipotential Surfaces (HL) (HL IB Physics)

Revision Note

Ann H

Author

Ann H

Expertise

Physics

Electric Equipotential Surfaces

  • Equipotential surfaces are lines of equal electric potential 
    • They are always perpendicular to the electric field lines
    • In a radial field, the equipotential lines are represented by concentric circles around the charge
    • The equipotential lines become farther away from each other with increasing radius
    • In a uniform electric field, the equipotential lines are equally spaced
  • If a charge moves along an equipotential surface (or line), no work is done
    • This means the potential energy of the charge does not change
  • Equipotential lines are used to represent potential gradient
  • For example, for a positive point charge: 
    • The lines become closer together nearer the charge, this represents the potential gradient becoming steeper
    • If a positive test charge is pushed towards the charge, more work must be done to move it gradually closer

4-2-equipotential-vs-field-lines-2

The left side image shows the equipotential lines for a point charge acting like contours on a map. They are perpendicular to the field lines, as shown on the right side image

Equipotential Surfaces & Electric Field Lines

  • Equipotential surfaces can be drawn to represent the electric potential for a number of scenarios, such as
    • for a point charge
    • for multiple charges (up to four point charges)
    • inside and outside solid and hollow charged conducting spheres
    • between two oppositely charged parallel plates

Equipotential surface for a point charge

  • In a radial field, such as around a point charge, the equipotential lines:
    • are concentric circles around the charge
    • become progressively further apart with distance

Electric Equipotential Lines 1

Equipotential lines for a radial electric field are concentric circles which increase in radius and are perpendicular to the field lines

  • If a charged conducting sphere replaced a point charge, the equipotential surface would be the same 

Equipotential surface for multiple charges

  • The equipotential surfaces for a dipole (two opposite charges) and for two like charges are shown below:

4-2-11-equipotential-surface-and-field-of-two-charges

The equipotential surface for multiple charges can be obtained by drawing curves which are perpendicular to the field lines

  • An equipotential surface between two opposite charges can be identified by a central line at a potential of 0 V
    • This is the point where the opposing potentials cancel
  • An equipotential surface between two like charges can be identified by a region of empty space between them
    • This is the point where the resultant field is zero

4-2-11-equipotential-surface-of-two-radial-fields

Equipotential lines show that the potential has the greatest value near the charge and decreases with distance

Equipotential surface between parallel plates

  • In a uniform field, such as between two parallel plates, the equipotential lines are:
    • horizontal straight lines
    • parallel
    • equally spaced

Electric Equipotential Lines 2

The equipotential lines for a uniform field are evenly spaced parallel lines which are perpendicular to the field lines

Worked example

In the following diagram, two electric charges are shown which include the electric field lines

10-1-4-we-equipotential-q-ib-hl

   

(a) Draw the lines of equipotential including at least four lines and at least one that encircles both charges

(b) By considering the field lines and equipotentials from part (a), state what can be assumed about the two charges

Answer:

Part (a)

  • The lines of equipotential need to be perpendicular to the field lines at all times
  • These lines are almost circular when they are near the charges
  • And when moving out further the lines of equipotential cover both charges.
  • The lines of equipotential can be seen below

10-1-4-we-equipotential-ans-ib-hl

Part (b)

  • It can be assumed that both charges are positive since the field lines point outwards.
  • It can also be assumed that the charge on the left has a larger charge than the charge on the right since:
    • It has a greater density of field lines
    • It has a larger sphere of influence shown by the lines of equipotential
    • The point of zero electric field strength between the two charges is closer to the right charge

Exam Tip

The distinction between radial and uniform fields is an important one, remember:

  • a radial field is made up of lines which follow the radius of a circle
  • a uniform field is made up of lines which are a uniform distance apart

When drawing equipotential lines, remember that they do not have arrows since they have no particular direction and are not vectors.

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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.