Coulomb’s law
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- Lehman College - Electric Charge and Coulomb’s Law
- University of Saskatchewan Pressbooks - Coulomb’s Law
- Khan Academy - Coulomb's law
- University of Florida - College of Liberal Arts and Sciences - Department of Physics - Coulomb’s Law
- The University of Texas at Austin - Coulomb's law
- Physics LibreTexts - Coulomb’s law
- University of Central Florida Pressbooks - Coulomb’s Law
- The Physics Classroom - Coulomb's Law
- National Center for Biotechnology Information - PubMed Central - Coulomb's law and the Hydrogen Spectrum
- Key People:
- Charles-Augustin de Coulomb
- Related Topics:
- Coulomb force
- On the Web:
- The University of Texas at Austin - Coulomb's law (Apr. 01, 2024)
Coulomb’s law, mathematical description of the electric force between charged objects. Formulated by the 18th-century French physicist Charles-Augustin de Coulomb, it is analogous to Isaac Newton’s law of gravity.
Both gravitational and electric forces decrease with the square of the distance between the objects, and both forces act along a line between them. In Coulomb’s law, however, the magnitude and sign of the electric force are determined by the electric charge, rather than the mass, of an object. Thus, charge determines how electromagnetism influences the motion of charged objects. Charge is a basic property of matter. Every constituent of matter has an electric charge with a value that can be positive, negative, or zero. For example, electrons are negatively charged, and atomic nuclei are positively charged. Most bulk matter has an equal amount of positive and negative charge and thus has zero net charge.
According to Coulomb, the electric force for charges at rest has the following properties:
- Like charges repel each other; unlike charges attract. Thus, two negative charges repel one another, while a positive charge attracts a negative charge.
- The attraction or repulsion acts along the line between the two charges.
- The size of the force varies inversely as the square of the distance between the two charges. Therefore, if the distance between the two charges is doubled, the attraction or repulsion becomes weaker, decreasing to one-fourth of the original value. If the charges come 10 times closer, the size of the force increases by a factor of 100.
- The size of the force is proportional to the value of each charge. The unit used to measure charge is the coulomb (C). If there were two positive charges, one of 0.1 coulomb and the second of 0.2 coulomb, they would repel each other with a force that depends on the product 0.2 × 0.1. Thus, if each of the charges were reduced by one-half, the repulsion would be reduced to one-quarter of its former value.