Vernier Software and Technology
Vernier Software & Technology

Mapping Electric Potential


Coulomb’s law describes how the force that charged objects exert on one another depends both on the magnitude of charge and the distance between the objects. However, it does not explain how this force is mediated between objects that are not in contact. For this, we need the concept of the field, which you may have addressed in your study of mechanics. We know that an object with mass experiences a force when it is placed in the gravitational field produced by another object with mass. Near the surface of an object as large as the Earth, the gravitational field is nearly constant and is directed downward, perpendicular to the surface. We assign the variable g to designate the strength of the gravitational field; its units are N/kg.

Charge, like mass, both produces and responds to a field–the electric field. Unlike the gravitational field near the surface of the Earth, the electric fields produced by the considerably smaller charged objects we examine in the lab are usually quite variable. Furthermore, the forces they exert can be repulsive as well as attractive. We cannot easily map the electric field produced by distributions of charge. However, we can measure the electric potential at various locations with a voltage probe. From a map of electric potential readings, we can deduce information about the strength and the direction of the electric field at these locations.

In your pre-lab discussion you will learn the concept of potential as a property of a location in a field. To better understand maps of electric potential, we turn to their gravitational analog: topographic maps. The lines on a topographic map indicate locations of equal gravitational potential (equipotentials) relative to some reference point (usually sea level). In this experiment, you will measure the electric potential at various locations in an electric field to determine an analogous map that will help you describe the electric field.


In this experiment, you will

  • Measure the electric potential at locations on a conducting surface resulting from various distributions of electric charge.
  • Use a Microsoft Excel spreadsheet and the electric potential data to generate 2-D and 3-D maps of electric equipotentials.
  • Analyze the maps of electric potential to sketch lines representing the electric field produced by electric charge.
  • Describe how the field from lines of charge differs from that produced by point sources.

Sensors and Equipment

This experiment features the following Vernier sensors and equipment.

Additional Requirements

You may also need an interface and software for data collection. What do I need for data collection?

Advanced Physics with Vernier — Beyond Mechanics

See other experiments from the lab book.

1Behavior of a Gas
2Heat Engines
3Standing Waves on a String
4Standing Waves in a Column of Air
5Doppler Effect
7Coulomb's Law
8Mapping Electric Potential
9Factors Affecting Electrical Resistance
10Series and Parallel Circuits
11Faraday’s Law: Moving Magnet
12Faraday’s Law: Alternating Current
13Capacitors and Inductors
14RLC Circuits
15Curved Mirrors and Images
16Thin Lenses and Real Images
17Thin Lenses and Virtual Images
18Aperture and Depth of Field
21Spectrum of Atomic Hydrogen
22Planck’s Constant

Experiment 8 from Advanced Physics with Vernier — Beyond Mechanics Lab Book

<i>Advanced Physics with Vernier — Beyond Mechanics</i> book cover

Included in the Lab Book

Vernier lab books include word-processing files of the student instructions, essential teacher information, suggested answers, sample data and graphs, and more.

Buy the Book

Dev Reference: VST0643

Go to top