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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]].  
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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 Ampère's original infinitesimal equation, which is not without problems,<ref>


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,
{{cite book |author=E. Whittaker |title=A History of the Theories of Aether and Electricity, vol. I |edition=Reprint of 1951 2nd edition |isbn=9780548967201 |year=2008|pages= pp. 85-88 |publisher=Kessinger Publishing, LLC |url=http://books.google.com/books?id=iXWcPwAACAAJ}} Also available as {{cite book |author=E. Whittaker |title=A History of the Theories of Aether and Electricity, vol. I |edition=Reprint of 1951 2nd edition |publisher=University of California Libraries  |isbn=1125241101 |year=2011
|url=http://www.amazon.com/gp/product/1125241101/ref=s9_simh_se_p14_d0_i2?pf_rd_m=ATVPDKIKX0DER&pf_rd_s=auto-no-results-center-1&pf_rd_r=074C2CW9QPDR859VQS5V&pf_rd_t=301&pf_rd_p=1263465782&pf_rd_i=0758163738}}
 
</ref><ref>
 
{{cite journal |author= C. Christodoulides |title=Comparison of the Ampère and Biot-Savart magnetostatic force laws in their line-current-element forms |journal= American Journal of Physics|volume=vol. 56 |pages= pp. 357-362 |year=1988|url=http://dx.doi.org/10.1119/1.15613}}
 
</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.
==Electromagnetic units==
Equations will be given in two common systems of  electromagnetic units ([[SI]] and [[Gaussian units]]) and to that end we define the  constant ''k'' as follows,<ref>
 
A discussion of the commonly used units is provided by {{cite book |title=Electromagnetic radiation: variational methods, waveguides and accelerators |author=Kimball A. Milton, Julian Schwinger |url= |chapter=Appendix: Electromagnetic units |pages=pp. 347 ''ff'' |url=http://books.google.com/books?id=x_h2rai2pYwC&pg=PA347 |isbn=3540293043 |publisher=Springer |year=2006}}
 
</ref>
:<math>
:<math>
k = \begin{cases}
k = \begin{cases}
{\displaystyle \frac{\mu_0\mu_r}{4\pi}} & \hbox{for SI units}\\
{\displaystyle \frac{\mu_0}{4\pi}} & \hbox{for SI units}\\
 
\\
{\displaystyle \frac{1}{c^2}} & \hbox{for Gaussian (rationalized cgs) units}.
{\displaystyle \frac{1}{c^2}} & \hbox{for Gaussian units}.
\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]] (also known as vacuum permeability). The quantity ''c'' is the [[speed of light]] in vacuum, in SI units a defined value denoted by ''c<sub>0</sub>'' = {{nowrap|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 unit of length) between them is,
{{Image|Parallel wires.PNG|right|200px|'''''B'''''-field from current ''i<sub>2</sub>'' in wire ''2'' causes force '''''F''''' on wire ''1''.}}
Consider two wires, one carrying an electric current ''i''<sub>1</sub>, the other ''i''<sub>2</sub>. Both currents are constant in time; the wires are infinite, straight, and parallel, and a distance ''r'' apart.
 
The [[magnetic flux density]] '''B<sub>2</sub>''' due to the wire with current  ''i<sub>2</sub>'' is directed in circles about wire ''2'', and at the distance ''r'' has magnitude (in SI units):<ref name=Seaway>
 
{{cite book |title=College Physics Volume 2: Chapters 15-30 |author=Raymond A. Serway, Jerry S. Faughn, Chris Vuille |chapter=§19.8: Magnetic force between two conductors |url=http://books.google.com/books?id=dUh9yMf40fIC&pg=PA645 |pages=p. 645 |isbn=0495554758 |year=2008 |edition=8th ed |publisher=Cengage Learning}}
 
</ref>
 
:<math>B_2 = \frac{\mu_0 i_2}{2\pi r} \ . </math>
 
The force '''F<sub>1</sub>''' on wire ''1'' due to this magnetic flux density is found regarding the current as a movement of charge. A wire carrying a current ''i<sub>2</sub>'' in time ''dt'' moves a charge ''q = i<sub>2</sub> dt''. In this time the charge moves a distance ''dℓ'' = ''v dt'' (with ''v'' the speed of the electrons traveling down the wire), suggesting ''i<sub>2</sub> dℓ'' = ''q v''. The [[Lorentz force]] upon the charge subject to magnetic flux density ''B'' perpendicular to the flow of charge is then radially directed with magnitude ''F<sub></sub> = qvB = i<sub>2</sub>B dℓ'', which is the force on each element of  length ''dℓ'' of the wire. Thus, the force per unit length upon wire ''1'' is:
 
:<math> F_1 = \frac{\mu_0 i_1 i_2 }{2\pi r } \, </math>
 
which is Ampère's law for the force per unit length ''l'' of wire. The force exerted by wire ''1'' on wire ''2'' has the same magnitude, so the subscript on the force is unnecessary. In general units, the force per unit length is:
:<math>
:<math>
F = 2 k \frac{i_1 i_2}{r}.\,  
F = 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]]). If ''r'' = 1 m,  F = 2 &sdot; 10<sup>&minus;7</sup> N (per meter of wire in vacuum), 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>.
The force ''F'' is attractive if the currents run in the same direction and repulsive if they flow in opposite direction.  
[[Image:Ampere equation.png|right|thumb|300px|Illustration to the force between two closed current-carrying loops]].
 
===Definition of the ampere===
This force between straight, parallel wires is used to define the [[SI unit]] of current, the [[ampere (unit)|ampere]], symbol ''A''.<ref name=BIPM>
 
The official definition is found at the [[BIPM]] website: {{cite web |title=Unit of electric current (ampere) |url=http://www.bipm.org/en/si/si_brochure/chapter2/2-1/ampere.html |accessdate=2011-04-20 |publisher=BIPM}}
 
 
</ref> Take two infinitely long wires in vacuum at a distance ''r'' = 1 m, consider the force that one meter of these wires exert on one another (''l'' = 1 m) and let this force be ''F'' = 2&sdot;10<sup>&minus;7</sup> N (newton). Then for  ''i''<sub>1</sub> = ''i''<sub>2</sub>  the current strengths are by definition both equal to one ampere (1 A). In SI units this implies that ''k'' = 10<sup>&minus;7</sup>  N/A<sup>2</sup> and hence that the magnetic constant is:
: &mu;<sub>0</sub> = 4&pi; ''k'' = 4&pi;&sdot;10<sup>&minus;7</sup> N/A<sup>2</sup>.
{{Image|Current elements.PNG|right|200px|Illustration of interacting current elements ''i<sub>1</sub>''d'''''l<sub>1</sub>''''' and ''i<sub>2</sub>''d'''''l<sub>2</sub>''''' from two closed current-carrying loops}}


==Two loops==
==Two loops==


Let <math>\scriptstyle i_1</math> and <math>\scriptstyle i_2</math> 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
Let <math>\scriptstyle i_1</math> and <math>\scriptstyle i_2</math> be electric currents constant in time. They run in separate loops (closed curves) ''C''<sub>1</sub> and ''C''<sub>2</sub>, 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
:<math>
:<math>
\mathbf{F}_{12} = -k i_1 i_2 \oint_{l_1}\oint_{l_2} \frac{ (d\mathbf{l}_1 \cdot d\mathbf{l}_2)\, \mathbf{r}_{12} }{|\mathbf{r}_{12}|^3}.
\mathbf{F}_{12} = -k i_1 i_2 \oint_{C_1}\oint_{C_2} \frac{ (d\boldsymbol{l}_1 \cdot d\boldsymbol{l}_2)\, \mathbf{r}_{12} }{|\mathbf{r}_{12}|^3}.
\qquad\qquad\qquad(1)
</math>
</math>
Here '''''r<sub>12</sub>''''' = '''''r<sub>1</sub>'''''−'''''r<sub>2</sub>''''' is the vector locating element ''1'' from the location of element ''2'', pointing from ''2'' to ''1''.
==Alternative expression==
One often finds the following expression for the force between two electric-current-carrying loops:<ref name=Neelakanta>
For example, {{cite book |title=Handbook of electromagnetic materials |author=Perambur S. Neelakanta |url=http://books.google.com/books?id=5w6fTx47MgsC&pg=PA10 |pages=p. 10 |isbn= 0849325005 |year=1995 |publisher=CRC Press}} and {{cite book |title=Electromagnetic field theory fundamentals |author=Bhag S. Guru, Hüseyin R. Hızıroğlu |url=http://books.google.com/books?id=b2f8rCngSuAC&pg=PA183 |pages=p. 183 |chapter=Ampère's force law |isbn=0521830168 |year=2004 |publisher=Cambridge University Press |edition=2nd ed}}
</ref>
:<math>
\mathbf{F}_{12} = k i_1 i_2 \oint_{C_1}\oint_{C_2} \frac{ d\boldsymbol{l}_1 \times(  d\boldsymbol{l}_2\,  \times \mathbf{r}_{12} )}{|\mathbf{r}_{12}|^3},
\qquad\qquad\ \ (2)
</math>
instead of the simpler expression in Eq. (1). Here the multiplication signs (&times;) indicate [[vector product]]s. The integrand [expression under the integral of Eq. (2)] follows from the [[Biot-Savart's law|Biot-Savart-Laplace]] expression for the magnetic induction '''B'''('''r'''<sub>1</sub>) due to a  segment of the second loop. Insertion of '''B'''('''r'''<sub>1</sub>) into the  [[Lorentz force]] that acts on the current in segment d'''l'''<sub>1</sub> gives the integrand of Eq. (2).
The labeling of the segments being arbitrary, one would expect the same force (in absolute value) when the labels 1 and 2 are interchanged, or in other words, one would expect  [[Isaac Newton|Newton]]'s third law  <math>\scriptstyle \mathbf{F}_{12} = -\mathbf{F}_{21}</math> (action is minus reaction) to hold. This is not the case, the integrand in equation (2) is non-symmetric under interchange of labels 1 and 2 and hence the integral also appears to be non-symmetric. However, after integration the expression becomes antisymmetric (changes sign under interchange of 1 and 2) and hence satisfies Newton's third law.
To see this we note that the force in Eq. (2) has in fact two contributions, as follows from a result well-known in [[vector analysis]],
:<math>
\frac{ d\boldsymbol{l}_1 \times(  d\boldsymbol{l}_2\,  \times \mathbf{r}_{12} )} {|\mathbf{r}_{12}|^3} =
\frac{(  d\boldsymbol{l}_1 \cdot  \mathbf{r}_{12} )\, d\boldsymbol{l}_2}{|\mathbf{r}_{12}|^3}  - \frac{(d\boldsymbol{l}_1 \cdot d\boldsymbol{l}_2)\, \mathbf{r}_{12}}{|\mathbf{r}_{12}|^3} .
</math>
The second contribution gives an integral that is obviously equal to Eq. (1), which is manifestly antisymmetric  under interchange of labels (the dot product does not change, the vector '''r'''<sub>12</sub> changes sign). We will show that the first contribution vanishes after integration over a closed curve.
Write
:<math>
\frac{\mathbf{r}_{12}}{|\mathbf{r}_{12}|^3} = -\boldsymbol{\nabla}_1 \left(\frac{1}{|\mathbf{r}_{12}|}\right) \equiv -\mathbf{A},
</math>
where '''A''' is a short hand notation.
Applying [[Stokes' theorem]], we find that the first contribution becomes
:<math>
-k i_1 i_2 \oint_{C_2}\left[ \oint_{C_1} (d\boldsymbol{l}_1 \cdot \mathbf{A})\,\right] d\boldsymbol{l}_2 = - k i_1 i_2 \oint_{C_2} \left[\iint_S  (\boldsymbol{\nabla}_1 \times \mathbf{A}) \cdot d\mathbf{S}_1 \, \right]d\boldsymbol{l}_2.
</math>
It is well-known in vector analysis that
:<math>
\boldsymbol{\nabla}_1 \times \boldsymbol{\nabla}_1 \Phi = 0
</math>
for any scalar function  &Phi; and in particular for &Phi; &equiv; 1/|'''r'''<sub>12</sub>|. Hence the first contribution to the force of Eq. (2) vanishes.
==History==
Ampère's original law for the force exerted upon element ''1'' by element ''2'' is ('''''û<sub>12</sub>''''' = −'''''û<sub>21</sub>'''''):<ref name=Assis>
See for example, {{cite book |title=Weber's electrodynamics |author=André Koch Torres Assis |pages=p. 86 |url=http://books.google.com/books?id=SpUHp9P9pxsC&pg=PA86 |isbn=0792331370 |year=1994 |publisher=Springer}}, or {{cite book |title=Inductance and force calculations in electrical circuits |author=Marcelo de Almeida Bueno, André Koch Torres Assis |chapter=§5.1: Ampère's force |pages=pp. 51 ''ff'' |url=http://books.google.com/books?id=td7jh429VGsC&pg=PA52 |isbn=9781560729174 |year=2001 |publisher=Nova Science Publishers}}
</ref>
:<math>d^2\mathbf{F_{21}} = -d^2\mathbf{F_{12}} =  -i_1i_2\frac{\mu_0} {4\pi}\ \frac{\mathbf{\hat{u}_{12}}}{r^2_{12}}\left( 2\ (d \boldsymbol{l_1 \cdot} d\boldsymbol{l_2})-3(  \mathbf{ \hat{u}_{12}\cdot } d\boldsymbol{ l_1} )(\mathbf{ \hat{u}_{12} \cdot}d\boldsymbol{l_2})\right ) \ , </math>
with '''û<sub>12</sub>''' a unit vector pointing along the line joining element ''2'' to element ''1'' and ''r<sub>12</sub>'' the length of this line. The force element is second order because it is a product of two infinitesimals. This force law leads to the same force between closed current loops as the more commonly used Grassmann's law presented above:
:<math>d^2\mathbf{F_{21}} = -i_1i_2\frac{\mu_0} {4\pi}\ \frac{1}{r^2_{12}}\left( \ (d \boldsymbol{l_1 \cdot} d\boldsymbol{l_2})\mathbf{\hat{u}_{12}}-(  \mathbf{ \hat{u}_{12}\cdot } d\boldsymbol{ l_1} )d\boldsymbol{l_2}\right ) \ , </math>
or, interchanging ''1'' and ''2'', the force on element ''2'' by element ''1'' is:
:<math>d^2\mathbf{F_{12}} = i_1i_2\frac{\mu_0} {4\pi}\ \frac{1}{r^2_{12}}\left( \ (d \boldsymbol{l_1 \cdot} d\boldsymbol{l_2})\mathbf{\hat{u}_{12}}-(  \mathbf{ \hat{u}_{12}\cdot } d\boldsymbol{ l_2} )d\boldsymbol{l_1}\right ) \ , </math>
which is not simply opposite in sign to the previous expression. Unlike Ampère's law, Grassmann's law is not antisymmetric under exchange of the indices ''1'' and ''2'', and violates [[Classical_mechanics#Newton.27s_laws_of_motion|Newton's law of action opposite to reaction]]. Grassmann's law is readily derived from the [[Biot-Savart law]], and is consistent with space-time symmetry. Its violation of Newton's law of action and reaction stems from its basis relying not upon action-at-a-distance, but being based instead upon a force mediated by a field, which itself has physical properties to take into account.<ref name=Phipps>
{{cite journal |author=Thomas E Phipps, Jr. |title=Weber-like laws of action-at-a-distance in modern physics |journal=Aperion |volume=No. 8 |date=Autumn, 1990 |pages=p. 18 |url=http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.1.3229&rep=rep1&type=pdf }}
</ref> There exists some debate over the ultimate form of the force law between current elements.<ref name=Graneau>
For a discussion, see {{cite journal |author=P Graneau and N Graneau |title=Electrodynamic force law controversy |journal=Phys Rev |volume =vol 63 |issue=Issue 5 |doi=10.1103/PhysRevE.63.058601 |year=2001}} and a series of essays in {{cite book |title=Instantaneous action at a distance in modern physics: "pro" and "contra" |editor=Andrew E. Chubykalo, Viv Pope, Roman Smirnov-Rueda, eds |url=http://books.google.com/books?hl=en&lr=&id=im-8ORsEm4AC&oi=fnd&pg=PA257 |isbn=1560726989 |year=1999 |publisher=Nova Science Publishers}}


==Reference==
</ref>
<references />


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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 Ampère's original 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.

Electromagnetic units

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

Here μ0 is the magnetic constant (also known as vacuum permeability). The quantity c is the speed of light in vacuum, in SI units a defined value denoted by c0 = 299 792 458 m s−1 (exactly).

Two straight, infinite, and parallel wires

(PD) Image: John R. Brews
B-field from current i2 in wire 2 causes force F on wire 1.

Consider two wires, one carrying an electric current i1, the other i2. Both currents are constant in time; the wires are infinite, straight, and parallel, and a distance r apart.

The magnetic flux density B2 due to the wire with current i2 is directed in circles about wire 2, and at the distance r has magnitude (in SI units):[4]

The force F1 on wire 1 due to this magnetic flux density is found regarding the current as a movement of charge. A wire carrying a current i2 in time dt moves a charge q = i2 dt. In this time the charge moves a distance dℓ = v dt (with v the speed of the electrons traveling down the wire), suggesting i2 dℓ = q v. The Lorentz force upon the charge subject to magnetic flux density B perpendicular to the flow of charge is then radially directed with magnitude F = qvB = i2B dℓ, which is the force on each element of length dℓ of the wire. Thus, the force per unit length upon wire 1 is:

which is Ampère's law for the force per unit length l of wire. The force exerted by wire 1 on wire 2 has the same magnitude, so the subscript on the force is unnecessary. In general units, the force per unit length is:

The force F is attractive if the currents run in the same direction and repulsive if they flow in opposite direction.

Definition of the ampere

This force between straight, parallel wires is used to define the SI unit of current, the ampere, symbol A.[5] Take two infinitely long wires in vacuum at a distance r = 1 m, consider the force that one meter of these wires exert on one another (l = 1 m) and let this force be F = 2⋅10−7 N (newton). Then for i1 = i2 the current strengths are by definition both equal to one ampere (1 A). In SI units this implies that k = 10−7 N/A2 and hence that the magnetic constant is:

μ0 = 4π k = 4π⋅10−7 N/A2.
(PD) Image: John R. Brews
Illustration of interacting current elements i1dl1 and i2dl2 from two closed current-carrying loops

Two loops

Let and be electric currents constant in time. They run in separate loops (closed curves) C1 and C2, 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

Here r12 = r1r2 is the vector locating element 1 from the location of element 2, pointing from 2 to 1.

Alternative expression

One often finds the following expression for the force between two electric-current-carrying loops:[6]

instead of the simpler expression in Eq. (1). Here the multiplication signs (×) indicate vector products. The integrand [expression under the integral of Eq. (2)] follows from the Biot-Savart-Laplace expression for the magnetic induction B(r1) due to a segment of the second loop. Insertion of B(r1) into the Lorentz force that acts on the current in segment dl1 gives the integrand of Eq. (2).

The labeling of the segments being arbitrary, one would expect the same force (in absolute value) when the labels 1 and 2 are interchanged, or in other words, one would expect Newton's third law (action is minus reaction) to hold. This is not the case, the integrand in equation (2) is non-symmetric under interchange of labels 1 and 2 and hence the integral also appears to be non-symmetric. However, after integration the expression becomes antisymmetric (changes sign under interchange of 1 and 2) and hence satisfies Newton's third law.

To see this we note that the force in Eq. (2) has in fact two contributions, as follows from a result well-known in vector analysis,

The second contribution gives an integral that is obviously equal to Eq. (1), which is manifestly antisymmetric under interchange of labels (the dot product does not change, the vector r12 changes sign). We will show that the first contribution vanishes after integration over a closed curve.

Write

where A is a short hand notation. Applying Stokes' theorem, we find that the first contribution becomes

It is well-known in vector analysis that

for any scalar function Φ and in particular for Φ ≡ 1/|r12|. Hence the first contribution to the force of Eq. (2) vanishes.

History

Ampère's original law for the force exerted upon element 1 by element 2 is (û12 = −û21):[7]

with û12 a unit vector pointing along the line joining element 2 to element 1 and r12 the length of this line. The force element is second order because it is a product of two infinitesimals. This force law leads to the same force between closed current loops as the more commonly used Grassmann's law presented above:

or, interchanging 1 and 2, the force on element 2 by element 1 is:

which is not simply opposite in sign to the previous expression. Unlike Ampère's law, Grassmann's law is not antisymmetric under exchange of the indices 1 and 2, and violates Newton's law of action opposite to reaction. Grassmann's law is readily derived from the Biot-Savart law, and is consistent with space-time symmetry. Its violation of Newton's law of action and reaction stems from its basis relying not upon action-at-a-distance, but being based instead upon a force mediated by a field, which itself has physical properties to take into account.[8] There exists some debate over the ultimate form of the force law between current elements.[9]

References

  1. E. Whittaker (2008). A History of the Theories of Aether and Electricity, vol. I, Reprint of 1951 2nd edition. Kessinger Publishing, LLC, pp. 85-88. ISBN 9780548967201.  Also available as E. Whittaker (2011). A History of the Theories of Aether and Electricity, vol. I, Reprint of 1951 2nd edition. University of California Libraries. ISBN 1125241101. 
  2. C. Christodoulides (1988). "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.
  3. A discussion of the commonly used units is provided by Kimball A. Milton, Julian Schwinger (2006). “Appendix: Electromagnetic units”, Electromagnetic radiation: variational methods, waveguides and accelerators. Springer, pp. 347 ff. ISBN 3540293043. 
  4. Raymond A. Serway, Jerry S. Faughn, Chris Vuille (2008). “§19.8: Magnetic force between two conductors”, College Physics Volume 2: Chapters 15-30, 8th ed. Cengage Learning, p. 645. ISBN 0495554758. 
  5. The official definition is found at the BIPM website: Unit of electric current (ampere). BIPM. Retrieved on 2011-04-20.
  6. For example, Perambur S. Neelakanta (1995). Handbook of electromagnetic materials. CRC Press, p. 10. ISBN 0849325005.  and Bhag S. Guru, Hüseyin R. Hızıroğlu (2004). “Ampère's force law”, Electromagnetic field theory fundamentals, 2nd ed. Cambridge University Press, p. 183. ISBN 0521830168. 
  7. See for example, André Koch Torres Assis (1994). Weber's electrodynamics. Springer, p. 86. ISBN 0792331370. , or Marcelo de Almeida Bueno, André Koch Torres Assis (2001). “§5.1: Ampère's force”, Inductance and force calculations in electrical circuits. Nova Science Publishers, pp. 51 ff. ISBN 9781560729174. 
  8. Thomas E Phipps, Jr. (Autumn, 1990). "Weber-like laws of action-at-a-distance in modern physics". Aperion No. 8: p. 18.
  9. For a discussion, see P Graneau and N Graneau (2001). "Electrodynamic force law controversy". Phys Rev vol 63 (Issue 5). DOI:10.1103/PhysRevE.63.058601. Research Blogging. and a series of essays in (1999) Andrew E. Chubykalo, Viv Pope, Roman Smirnov-Rueda, eds: Instantaneous action at a distance in modern physics: "pro" and "contra". Nova Science Publishers. ISBN 1560726989.