Ampere's equation: Difference between revisions

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In [[physics]], more particularly in [[electrodynamics]],  '''Ampère's equation''' describes the force between two infinitesimal elements of current-carrying wires. The equation is named for the early nineteenth century French physicist and mathematician [[André-Marie Ampère]].  
In [[physics]], more particularly in [[electrodynamics]],  '''Ampère's equation''' describes the force between two infinitesimal elements of electric-current-carrying wires. The equation is named for the early nineteenth century French physicist and mathematician [[André-Marie Ampère]].  


Rather than giving the infinitesimal equation, which is not without problems,<ref>E. Whittaker, ''A History of the Theories of Aether and Electricity'', vol. I, 2nd edition, Nelson, London (1951). Reprinted by the American Institute of Physics, (1987). pp. 85-88 </ref><ref>C. Christodoulides, ''Comparison of the Ampère and Biot-Savart magnetostatic force laws in their line-current-element forms'', American Journal of Physics, vol. '''56''', pp. 357-362  (1988) </ref> we will describe two common integrated cases: two straight wires and two closed loops. The equations for these systems are generally accepted and are in full agreement with experiment.  
Rather than giving the infinitesimal equation, which is not without problems,<ref>E. Whittaker, ''A History of the Theories of Aether and Electricity'', vol. I, 2nd edition, Nelson, London (1951). Reprinted by the American Institute of Physics, (1987). pp. 85-88 </ref><ref>C. Christodoulides, ''Comparison of the Ampère and Biot-Savart magnetostatic force laws in their line-current-element forms'', American Journal of Physics, vol. '''56''', pp. 357-362  (1988) </ref> we will describe two common cases obtained by integration: a system consisting of two straight wires and a system of two closed loops. Since the integrals over disputed terms in Ampère's infinitesimal equation vanish, the equations for these integrated systems are generally accepted and, moreover, are in full agreement with experiment.  


Equations<ref>J. D. Jackson, ''Classical Electrodynamics'', 2nd edition, John Wiley, New York (1975) pp. 172-173</ref>  will be given in two common systems of  electromagnetic units ([[SI]] and rationalized Gaussian) and to that end we define the  constant ''k'' as follows,
Equations<ref>J. D. Jackson, ''Classical Electrodynamics'', 2nd edition, John Wiley, New York (1975) pp. 172-173</ref>  will be given in two common systems of  electromagnetic units ([[SI]] and rationalized Gaussian) and to that end we define the  constant ''k'' as follows,
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\end{cases}
\end{cases}
</math>
</math>
Here &mu;<sub>0</sub> is the [[magnetic constant|magnetic permeability]] of the vacuum and &mu;<sub>''r''</sub> is the relative magnetic permeability. The quantity ''c'' is the velocity of light in the vacuum (299&thinsp;792&thinsp;458&thinsp;m&thinsp;s<sup>&minus;1</sup> exactly) .  
Here &mu;<sub>0</sub> is the [[magnetic constant|permeability]] of the vacuum and &mu;<sub>''r''</sub> is the relative permeability. The quantity ''c'' is the velocity of light in the vacuum (299&thinsp;792&thinsp;458&thinsp;m&thinsp;s<sup>&minus;1</sup> exactly) .  


==Two straight, infinite, and parallel wires==
==Two straight, infinite, and parallel wires==
Consider two wires, one carrying a current <math>\scriptstyle i_1</math>, the other <math>\scriptstyle i_2</math>. Both currents are constant in time; the wires are infinite, straight, and parallel. If the wires are a distance ''r'' apart, the force (per length ''l'' of wire) between them is,
Consider two wires, one carrying an electric current <math>\scriptstyle i_1</math>, the other <math>\scriptstyle i_2</math>. Both currents are constant in time; the wires are infinite, straight, and parallel. If the wires are a distance ''r'' apart, the force (per length ''l'' of wire) between them is,
:<math>
:<math>
\frac{F}{l} = 2 k \frac{i_1 i_2}{r}.\,  
\frac{F}{l} = 2 k \frac{i_1 i_2}{r}.\,  
</math>
</math>
The force is attractive if the currents run in the same direction and repulsive if they flow in opposite direction. This equation is used to define the SI unit of current A ([[ampere (unit)|ampere]]). Wires in vacuum, ''r'' = 1 m, ''l'' = 1 m,  F = 2 &sdot; 10<sup>&minus;7</sup> N , and the currents are equal, then the currents are equal to 1 A. Note that in SI units this implies that &mu;<sub>0</sub> = 4&pi; &sdot; 10<sup>&minus;7</sup> N/A<sup>2</sup>.
The force is attractive if the currents run in the same direction and repulsive if they flow in opposite direction. This equation is used to define the SI unit of current A ([[ampere (unit)|ampere]]). Take wires in vacuum, ''r'' = 1 m, ''l'' = 1 m,  F = 2 &sdot; 10<sup>&minus;7</sup> N , and equal currents, then the currents are equal to 1 A. Note that in SI units this implies that &mu;<sub>0</sub> = 4&pi; &sdot; 10<sup>&minus;7</sup> N/A<sup>2</sup>.
[[Image:Ampere equation.png|right|thumb|300px|Illustration to the force between two closed current-carrying loops]].
[[Image:Ampere equation.png|right|thumb|300px|Illustration to the force between two closed current-carrying loops]].



Revision as of 09:19, 19 February 2008

In physics, more particularly in electrodynamics, Ampère's equation describes the force between two infinitesimal elements of electric-current-carrying wires. The equation is named for the early nineteenth century French physicist and mathematician André-Marie Ampère.

Rather than giving the infinitesimal equation, which is not without problems,[1][2] we will describe two common cases obtained by integration: a system consisting of two straight wires and a system of two closed loops. Since the integrals over disputed terms in Ampère's infinitesimal equation vanish, the equations for these integrated systems are generally accepted and, moreover, are in full agreement with experiment.

Equations[3] will be given in two common systems of electromagnetic units (SI and rationalized Gaussian) and to that end we define the constant k as follows,

Here μ0 is the permeability of the vacuum and μr is the relative permeability. The quantity c is the velocity of light in the vacuum (299 792 458 m s−1 exactly) .

Two straight, infinite, and parallel wires

Consider two wires, one carrying an electric current , the other . Both currents are constant in time; the wires are infinite, straight, and parallel. If the wires are a distance r apart, the force (per length l of wire) between them is,

The force is attractive if the currents run in the same direction and repulsive if they flow in opposite direction. This equation is used to define the SI unit of current A (ampere). Take wires in vacuum, r = 1 m, l = 1 m, F = 2 ⋅ 10−7 N , and equal currents, then the currents are equal to 1 A. Note that in SI units this implies that μ0 = 4π ⋅ 10−7 N/A2.

Illustration to the force between two closed current-carrying loops

.

Two loops

Let and be electric currents constant in time. They run in separate loops, see figure on the right, where all quantities are defined. The total force between two loops is given by the double path integral over the loops

References

  1. E. Whittaker, A History of the Theories of Aether and Electricity, vol. I, 2nd edition, Nelson, London (1951). Reprinted by the American Institute of Physics, (1987). pp. 85-88
  2. C. Christodoulides, Comparison of the Ampère and Biot-Savart magnetostatic force laws in their line-current-element forms, American Journal of Physics, vol. 56, pp. 357-362 (1988)
  3. J. D. Jackson, Classical Electrodynamics, 2nd edition, John Wiley, New York (1975) pp. 172-173