electromagnetism In physics, electromagnetism is an interaction that occurs between particles with electric charge via electromagnetic fields. The electromagnetic force is one of the four fundamental forces of nature. It is the dominant force in the interacti ...

, a magnetic dipole is the limit of either a closed loop of

electric current An electric current is a flow of charged particles, such as electrons or ions, moving through an electrical conductor or space. It is defined as the net rate of flow of electric charge through a surface. The moving particles are called charge c ...

or a pair of poles as the size of the source is reduced to zero while keeping the

magnetic moment In electromagnetism, the magnetic moment or magnetic dipole moment is the combination of strength and orientation of a magnet or other object or system that exerts a magnetic field. The magnetic dipole moment of an object determines the magnitude ...

constant. It is a magnetic analogue of the

electric dipole The electric dipole moment is a measure of the separation of positive and negative electrical charges within a system: that is, a measure of the system's overall polarity. The SI unit for electric dipole moment is the coulomb-metre (C⋅m). The ...

, but the analogy is not perfect. In particular, a true

magnetic monopole In particle physics, a magnetic monopole is a hypothetical particle that is an isolated magnet with only one magnetic pole (a north pole without a south pole or vice versa). A magnetic monopole would have a net north or south "magnetic charge". ...

, the magnetic analogue of an

electric charge Electric charge (symbol ''q'', sometimes ''Q'') is a physical property of matter that causes it to experience a force when placed in an electromagnetic field. Electric charge can be ''positive'' or ''negative''. Like charges repel each other and ...

, has never been observed in nature. However, magnetic monopole

quasiparticles In condensed matter physics, a quasiparticle is a concept used to describe a collective behavior of a group of particles that can be treated as if they were a single particle. Formally, quasiparticles and collective excitations are closely relate ...

have been observed as emergent properties of certain condensed matter systems. Moreover, one form of magnetic dipole moment is associated with a fundamental quantum property—the spin of

elementary particles In particle physics, an elementary particle or fundamental particle is a subatomic particle that is not composed of other particles. The Standard Model presently recognizes seventeen distinct particles—twelve fermions and five bosons. As a con ...

. Because magnetic monopoles do not exist, the magnetic field at a large distance from any static magnetic source looks like the field of a dipole with the same dipole moment. For higher-order sources (e.g. quadrupoles) with no dipole moment, their field decays towards zero with distance faster than a dipole field does.

External magnetic field produced by a magnetic dipole moment

classical physics Classical physics refers to physics theories that are non-quantum or both non-quantum and non-relativistic, depending on the context. In historical discussions, ''classical physics'' refers to pre-1900 physics, while '' modern physics'' refers to ...

, 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

constant. For the current loop, this limit is most easily derived from the

vector potential In vector calculus, a vector potential is a vector field whose curl is a given vector field. This is analogous to a ''scalar potential'', which is a scalar field whose gradient is a given vector field. Formally, given a vector field \mathbf, a ' ...

: :

()=\frac\frac=\frac\frac,

where ''μ''₀ is the

vacuum permeability The vacuum magnetic permeability (variously ''vacuum permeability'', ''permeability of free space'', ''permeability of vacuum'', ''magnetic constant'') is the magnetic permeability in a classical vacuum. It is a physical constant, conventionally ...

constant and is the surface of a sphere of radius . The magnetic flux density (strength of the B-field) is then :

\mathbf()=\nabla\times=\frac\left frac-\frac\right

Alternatively one can obtain the

scalar potential In mathematical physics, scalar potential describes the situation where the difference in the potential energies of an object in two different positions depends only on the positions, not upon the path taken by the object in traveling from one p ...

first from the magnetic pole limit, :

\psi()=\frac,

and hence the magnetic field strength (or strength of the H-field) is :

= \frac.

The magnetic field strength is symmetric under rotations about the axis of the magnetic moment. In spherical coordinates, with

\mathbf = \mathbf\cos\theta - \boldsymbol\sin\theta

, and with the magnetic moment aligned with the z-axis, then the field strength can more simply be expressed as :

\mathbf()=\frac \left (
2 \cos \theta \, \mathbf + \sin \theta \, \boldsymbol \right ) .

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 (above for mobile users)). 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(\mathbf)=\frac\left frac + \frac\mathbf\delta(\mathbf)\right

where is the

Dirac delta function In mathematical analysis, the Dirac delta function (or distribution), also known as the unit impulse, is a generalized function on the real numbers, whose value is zero everywhere except at zero, and whose integral over the entire real line ...

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 pole-charge and distance constant, the limiting field is :

\mathbf(\mathbf) =\frac\left frac - \frac\mathbf\delta(\mathbf)\right

These fields are related by , where :

\mathbf(\mathbf) = \mathbf\delta(\mathbf)

is the

magnetization In classical electromagnetism, magnetization is the vector field that expresses the density of permanent or induced magnetic dipole moments in a magnetic material. Accordingly, physicists and engineers usually define magnetization as the quanti ...

Forces between two magnetic dipoles

The force exerted by one dipole moment on another separated in space by a vector can be calculated using: :

\mathbf = \nabla\left(\mathbf_2\cdot\mathbf_1\right),

or :

\mathbf(\mathbf, \mathbf_1, \mathbf_2) = \dfrac\left \mathbf_1\cdot\mathbf)\mathbf_2 + (\mathbf_2\cdot\mathbf)\mathbf_1 + (\mathbf_1\cdot\mathbf_2)\mathbf - \dfrac\mathbf\right

where is the distance between dipoles. The force acting on is in the opposite direction. The torque can be obtained from the formula :

\boldsymbol=\mathbf_2 \times \mathbf_1.

Dipolar fields from finite sources

The

magnetic scalar potential Magnetic scalar potential, ''ψ'', is a quantity in classical electromagnetism analogous to electric potential. It is used to specify the magnetic H-field in cases when there are no free currents, in a manner analogous to using the electric ...

produced by a finite source, but external to it, can be represented by a

multipole expansion A multipole expansion is a mathematical series representing a function that depends on angles—usually the two angles used in the spherical coordinate system (the polar and azimuthal angles) for three-dimensional Euclidean space, \R^3. Multipo ...

. Each term in the expansion is associated with a characteristic moment and a potential having a characteristic rate of decrease with distance from the source. Monopole moments have a rate of decrease, dipole moments have a rate, quadrupole moments have a rate, and so on. The higher the order, the faster the potential drops off. Since the lowest-order term observed in magnetic sources is the dipole term, it dominates at large distances. Therefore, at large distances any magnetic source looks like a dipole of the same

Notes

References

* * * * {{Refend Magnetostatics Magnetism Electric and magnetic fields in matter