The
magnetic field and
magnetic moment, due to natural magnetic dipoles (left), or an
electric current (right). Either generates the same field profile.
^{[1]}
A magnetic dipole is the limit of either a closed loop of electric current or a pair of poles as the dimensions of the source are reduced to zero while keeping the magnetic moment constant. It is a magnetic analogue of the electric dipole, but the analogy is not complete. In particular, a magnetic monopole, the magnetic analogue of an electric charge, has never been observed. Moreover, one form of magnetic dipole moment is associated with a fundamental quantum property—the spin of elementary particles.
The magnetic field around any magnetic source looks increasingly like the field of a magnetic dipole as the distance from the source increases.
Contents

External magnetic field produced by a magnetic dipole moment 1

Internal magnetic field of a dipole 2

Forces between two magnetic dipoles 3

Dipolar fields from finite sources 4

Notes 5

References 6
External magnetic field produced by a magnetic dipole moment
An electrostatic analogue for a magnetic moment: two opposing charges separated by a finite distance. Each arrow represents the direction of the field vector at that point.
The magnetic field of a current loop. The ring represents the current loop, which goes into the page at the x and comes out at the dot.
In classical physics, the magnetic field of a dipole is calculated as the limit of either a current loop or a pair of charges as the source shrinks to a point while keeping the magnetic moment m constant. For the current loop, this limit is most easily derived for the vector potential. Outside of the source region, this potential is (in SI units) ^{[2]}

{\mathbf{A}}({\mathbf{r}})=\frac{\mu_{0}}{4\pi r^{2}}\frac\times{\mathbf{r}}}{r}=\frac{\mu_{0}}{4\pi}\frac\times{\mathbf{r}}}{r^{3}},
with 4π r^{2} being the surface of a sphere of radius r;
and the magnetic flux density (strength of the Bfield) in teslas is

\mathbf{B}({\mathbf{r}})=\nabla\times{\mathbf{A}}=\frac{\mu_{0}}{4\pi}\left(\frac{3\mathbf{r}(\mathbf{m}\cdot\mathbf{r})}{r^{5}}\frac}{r^{3}}\right).
Alternatively one can obtain the scalar potential first from the magnetic pole limit,

\psi({\mathbf{r}})=\frac\cdot{\mathbf{r}}}{4\pi r^{3}},
and hence the magnetic field strength (or strength of the Hfield) in ampereturns per meter is

{\mathbf{H}}({\mathbf{r}})=\nabla\psi=\frac{1}{4\pi}\left(\frac{3\mathbf{r}(\mathbf{m}\cdot\mathbf{r})}{r^{5}}\frac}{r^{3}}\right) = \mathbf{B}/\mu_0.
The magnetic field is symmetric under rotations about the axis of the magnetic moment.
Internal magnetic field of a dipole
The two models for a dipole (current loop and magnetic poles) give the same predictions for the magnetic field far from the source. However, inside the source region they give different predictions. The magnetic field between poles is in the opposite direction to the magnetic moment (which points from the negative charge to the positive charge), while inside a current loop it is in the same direction (see the figure to the right). Clearly, the limits of these fields must also be different as the sources shrink to zero size. This distinction only matters if the dipole limit is used to calculate fields inside a magnetic material.
If a magnetic dipole is formed by making a current loop smaller and smaller, but keeping the product of current and area constant, the limiting field is

\mathbf{B}(\mathbf{x})=\frac{\mu_0}{4\pi}\left[\frac{3\mathbf{n}(\mathbf{n}\cdot \mathbf{m})\mathbf{m}}{\mathbf{x}^3} + \frac{8\pi}{3}\mathbf{m}\delta(\mathbf{x})\right],
where n=x/x is a unit vector, and δ(x) is the Dirac delta function in three dimensions. Unlike the expressions in the previous section, this limit is correct for the internal field of the dipole.
If a magnetic dipole is formed by taking a "north pole" and a "south pole", bringing them closer and closer together but keeping the product of magnetic polecharge and distance constant, the limiting field is

\mathbf{H}(\mathbf{x}) =\frac{1}{4\pi}\left[\frac{3\mathbf{n}(\mathbf{n}\cdot \mathbf{m})\mathbf{m}}{\mathbf{x}^3}  \frac{4\pi}{3}\mathbf{m}\delta(\mathbf{x})\right].
These fields are related by B = μ_{0}(H+M), where

\mathbf{M}(\mathbf{x}) = \mathbf{m}\delta(\mathbf{x})
is the magnetization.
Forces between two magnetic dipoles
The force F exerted by one dipole moment m_{1} on another m_{2} separated in space by a vector r can be calculated using:^{[3]}

\bold F = \nabla\left(\bold m_2\cdot\bold B_1\right),
or ^{[4]}^{[5]}

\bold F(\bold r,\bold m_1,\bold m_2) = \dfrac{3\mu_0}{4\pi\bold r^5}\left[(\bold m_1\cdot\bold r)\bold m_2 + (\bold m_2\cdot\bold r)\bold m_1 + (\bold m_1\cdot\bold m_2)\bold r  \dfrac{5(\bold m_1\cdot\bold r)(\bold m_2\cdot\bold r)}{\bold r^2}\bold r\right],
where r is the distance between dipoles. The force acting on m_{1} is in the opposite direction.
The torque can be obtained from the formula

\boldsymbol\tau =\bold m_2\times\bold B_1.
Dipolar fields from finite sources
The magnetic scalar potential ψ produced by a finite source, but external to it, can be represented by a multipole expansion. Each term in the expansion is associated with a characteristic moment and a potential having a characteristic rate of decrease with distance r from the source. Monopole moments have a 1/r rate of decrease, dipole moments have a 1/r^{2} rate, quadrupole moments have a 1/r^{3} rate, and so on. The higher the order, the faster the potential drops off. Since the lowestorder term observed in magnetic sources is the dipolar term, it dominates at large distances. Therefore, at large distances any magnetic source looks like a dipole with the same magnetic moment.
Notes

^ I.S. Grant, W.R. Phillips (2008). Electromagnetism (2nd ed.). Manchester Physics, John Wiley & Sons.

^ Chow 2006, pp. 146–150

^ D.J. Griffiths (2007). Introduction to Electrodynamics (3rd ed.). Pearson Education. p. 276.

^ Furlani 2001, p. 140

^ K.W. Yung, P.B. Landecker, D.D. Villani (1998). "An Analytic Solution for the Force between Two Magnetic Dipoles" (PDF). Retrieved November 24, 2012.
References

Chow, Tai L. (2006). Introduction to electromagnetic theory: a modern perspective.

Jackson, John D. (1999). Classical Electrodynamics (3rd ed.).

Furlani, Edward P. (2001). Permanent Magnet and Electromechanical Devices: Materials, Analysis, and Applications.

Schill, R. A. (2003). "General relation for the vector magnetic field of a circular current loop: A closer look".
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