Capacitance: Difference between revisions

Revision as of 20:26, 30 January 2020

Figure 1. Drawing of a capacitor with the capacitance, 400 microfarads, marked on the side.^[1]

Capacitance is the ability of an object (material in a particular geometry) to store an electric charge. Specifically, it is a measure of an isolated conductor's ability to store charge at a given voltage difference.^[2] In this sense, an object's capacitance is the ratio between its charge at a particular voltage difference and that voltage difference. Functionally, this leads to capacitance also being a measure of how much energy a capacitor can store.

Often a capacitance is thought of as being the physical property of a capacitor that has two conducting plates close to each other. The capacitance is described mathematically as:

[math]C[/math] is the capacitance, measured in farads
[math]q[/math] is the charge that is on the positive plate of the capacitor, measured in coulombs
[math]V[/math] is the voltage of the conductor, measured in volts

Capacitance is measured in farads (F), with 1 farad representing 1 coulomb per volt. This means that if an isolated conductor had a capacitance of 1 farad and was charged with 1 coulomb, it would have a voltage of 1 volt on its surface. There is also an alternate way to determine the capacitance of a capacitor if its dimensions are known. If the area of the plates of the capacitor can be determined, the capacitance can be calculated from the expression:^[3]

[math]C[/math] is the capacitance, measured in farads (F)
[math]\varepsilon_{0}[/math] is a constant called the permittivity of free space = 8.854188x10^-12 F/m ^[4]
[math]\varepsilon_{r}[/math] is the relative permittivity of the material between the plates
[math]A[/math] is the surface area of the plates of the capacitor, measured in square metres (m²)
[math]d[/math] is the distance between the plates, measured in metres (m)

The equation shows that the capacitance is influenced by the dimensions of the capacitor.

For Further Reading

References

↑ "Electrolytic Capacitor, Radial, 16x30 (Coloured)" Licensed under Public Domain via Wikimedia Commons - http://commons.wikimedia.org/wiki/File:Electrolytic_Capacitor,_Radial,_16x30_(Coloured).svg#/media/File:Electrolytic_Capacitor,_Radial,_16x30_(Coloured).svg
↑ P. Tipler and G. Mosca, "Electrostatic Energy and Capacitance," in Physics for Scientists and Engineers Volume 2, 5th ed. Freeman, ch. 24, pp. 752-755
↑ R. Kotz and M. Carlen, "Principles and applications of electrochemical capacitors," Electrochim. Acta, vol. 45, no. 15-16, pp. 2483-2498, May 2000.
↑ A. D. McNaught and A. Wilkinson. (2012, September 8). Permmittivity of vacuum [Online]. Available: http://goldbook.iupac.org/P04508.html

[1] "Electrolytic Capacitor, Radial, 16x30 (Coloured)" Licensed under Public Domain via Wikimedia Commons - http://commons.wikimedia.org/wiki/File:Electrolytic_Capacitor,_Radial,_16x30_(Coloured).svg#/media/File:Electrolytic_Capacitor,_Radial,_16x30_(Coloured).svg

[A-2] P. Tipler and G. Mosca, "Electrostatic Energy and Capacitance," in Physics for Scientists and Engineers Volume 2, 5th ed. Freeman, ch. 24, pp. 752-755

[3] R. Kotz and M. Carlen, "Principles and applications of electrochemical capacitors," Electrochim. Acta, vol. 45, no. 15-16, pp. 2483-2498, May 2000.

[4] A. D. McNaught and A. Wilkinson. (2012, September 8). Permmittivity of vacuum [Online]. Available: http://goldbook.iupac.org/P04508.html

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-[[Category:Done 2018-07-20]]
+[[Category:Done 2020-01-31]]
 [[File:capacitor4.png|400px|framed|right|Figure 1. Drawing of a capacitor with the capacitance, 400 microfarads, marked on the side.<ref>"Electrolytic Capacitor, Radial, 16x30 (Coloured)" Licensed under Public Domain via Wikimedia Commons - http://commons.wikimedia.org/wiki/File:Electrolytic_Capacitor,_Radial,_16x30_(Coloured).svg#/media/File:Electrolytic_Capacitor,_Radial,_16x30_(Coloured).svg</ref>]]
-<onlyinclude>'''Capacitance''' is the ability of an object or material to store an electric [[charge]]. Specifically, it is a measure of an isolated [[conductor]]'s ability to store charge at a given [[voltage difference]].</onlyinclude><ref name = A>P. Tipler and G. Mosca, "Electrostatic Energy and Capacitance," in ''Physics for Scientists and Engineers Volume 2,'' 5th ed. Freeman, ch. 24, pp. 752-755</ref> In this sense, an object's capacitance is the ratio between its charge at a particular voltage difference and that voltage difference. Functionally, this leads to capacitance also being a measure of how much [[energy]] a [[capacitor#Energy in a capacitor|capacitor can store]].
+<onlyinclude>'''Capacitance''' is the ability of an object (material in a particular geometry) to store an electric [[charge]]. Specifically, it is a measure of an isolated [[conductor]]'s ability to store charge at a given [[voltage difference]].</onlyinclude><ref name = A>P. Tipler and G. Mosca, "Electrostatic Energy and Capacitance," in ''Physics for Scientists and Engineers Volume 2,'' 5th ed. Freeman, ch. 24, pp. 752-755</ref> In this sense, an object's capacitance is the ratio between its charge at a particular voltage difference and that voltage difference. Functionally, this leads to capacitance also being a measure of how much [[energy]] a [[capacitor#Energy in a capacitor|capacitor can store]].
 Often a capacitance is thought of as being the physical property of a [[capacitor]] that has two conducting plates close to each other. The capacitance is described mathematically as:

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Capacitance: Difference between revisions

Revision as of 20:26, 30 January 2020

For Further Reading

References