Demagnetizing field

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The demagnetizing field, also called the stray field (outside the magnet), is the magnetic field (H-field)^[1] generated by the magnetization in a magnet. The total magnetic field in a region containing magnets is the sum of the demagnetizing fields of the magnets and the magnetic field due to any free currents or displacement currents. The term demagnetizing field reflects its tendency to act on the magnetization so as to reduce the total magnetic moment. It gives rise to shape anisotropy in ferromagnets with a single magnetic domain and to magnetic domains in larger ferromagnets.

The demagnetizing field of an arbitrarily shaped object requires a numerical solution of Poisson's equation even for the simple case of uniform magnetization. For the special case of ellipsoids (including infinite cylinders) the demagnetization field is linearly related to the magnetization by a geometry dependent constant called the demagnetizing factor. Since the magnetization of a sample at a given location depends on the total magnetic field at that point, the demagnetization factor must be used in order to accurately determine how a magnetic material responds to a magnetic field. (See magnetic hysteresis.)

Template:Main In general the demagnetizing field is a function of position Template:Math. It is derived from the magnetostatic equations for a body with no electric currents.^[2] These are Ampère's law
Template:NumBlk and Gauss's law
Template:NumBlk The magnetic field and flux density are related by^[3][4]
Template:NumBlk where ${\displaystyle {\mu }_0}$ is the permeability of vacuum and Template:Math is the magnetisation.

Template:Main The general solution of the first equation can be expressed as the gradient of a scalar potential Template:Math: Template:NumBlk

Inside the magnetic body, the potential Template:Math is determined by substituting (Template:EquationNote) and (Template:EquationNote) in (Template:EquationNote): Template:NumBlk

Outside the body, where the magnetization is zero, Template:NumBlk

At the surface of the magnet, there are two continuity requirements:^[3]

• The component of Template:Math parallel to the surface must be continuous (no jump in value at the surface).
• The component of Template:Math perpendicular to the surface must be continuous.

This leads to the following boundary conditions at the surface of the magnet: Template:NumBlk Here Template:Math is the surface normal and $\partial /\partial n$ is the derivative with respect to distance from the surface.^[5]

The outer potential Template:Math must also be regular at infinity: both Template:Math and Template:Math must be bounded as Template:Math goes to infinity. This ensures that the magnetic energy is finite.^[6] Sufficiently far away, the magnetic field looks like the field of a magnetic dipole with the same moment as the finite body.

Template:Main Any two potentials that satisfy equations (Template:EquationNote), (Template:EquationNote) and (Template:EquationNote), along with regularity at infinity, have identical gradients. The demagnetizing field Template:Math is the gradient of this potential (equation Template:EquationNote).

The energy of the demagnetizing field is completely determined by an integral over the volume Template:Math of the magnet:

Template:NumBlk

Suppose there are two magnets with magnetizations Template:Math and Template:Math. The energy of the first magnet in the demagnetizing field Template:Math of the second is

Template:NumBlk

The reciprocity theorem states that^[5]

Template:NumBlk

Formally, the solution of the equations for the potential is

Template:NumBlk where Template:Math is the variable to be integrated over the volume of the body in the first integral and the surface in the second, and Template:Math is the gradient with respect to this variable.^[5]

Qualitatively, the negative of the divergence of the magnetization Template:Math (called a volume pole) is analogous to a bulk bound electric charge in the body while Template:Math (called a surface pole) is analogous to a bound surface electric charge. Although the magnetic charges do not exist, it can be useful to think of them in this way. In particular, the arrangement of magnetization that reduces the magnetic energy can often be understood in terms of the pole-avoidance principle, which states that the magnetization tries to reduce the poles as much as possible.^[5]

<imagemap>File:SingleDomainMagneticCharges.svg|thumb|right|Illustration of the magnetic charges at the surface of a single-domain ferromagnet. The arrows indicate the direction of magnetization. The thickness of the colored region indicates the surface charge density. default direct SVG link </imagemap> One way to remove the magnetic poles inside a ferromagnet is to make the magnetization uniform. This occurs in single-domain ferromagnets. This still leaves the surface poles, so division into domains reduces the poles furtherTemplate:Clarify. However, very small ferromagnets are kept uniformly magnetized by the exchange interaction.

The concentration of poles depends on the direction of magnetization (see the figure). If the magnetization is along the longest axis, the poles are spread across a smaller surface, so the energy is lower. This is a form of magnetic anisotropy called shape anisotropy.

If the ferromagnet is large enough, its magnetization can divide into domains. It is then possible to have the magnetization parallel to the surface. Within each domain the magnetization is uniform, so there are no volume poles, but there are surface poles at the interfaces (domain walls) between domains. However, these poles vanish if the magnetic moments on each side of the domain wall meet the wall at the same angle (so that the components Template:Math are the same but opposite in sign). Domains configured this way are called closure domains.

An arbitrarily shaped magnetic object has a total magnetic field that varies with location inside the object and can be quite difficult to calculate. This makes it very difficult to determine the magnetic properties of a material such as, for instance, how the magnetization of a material varies with the magnetic field. For a uniformly magnetized sphere in a uniform magnetic field Template:Math the internal magnetic field Template:Math is uniform:

Template:NumBlk

where Template:Math is the magnetization of the sphere and Template:Math is called the demagnetizing factor, which assumes values between 0 and 1, and equals Template:Math for a sphere in SI units.^[3][4][7] Note that in cgs units Template:Math assumes values between 0 and Template:Math.

This equation can be generalized to include ellipsoids having principal axes in x, y, and z directions such that each component has a relationship of the form:^[4]

Template:NumBlk

Other important examples are an infinite plate (an ellipsoid with two of its axes going to infinity) which has Template:Math (SI units) in a direction normal to the plate and zero otherwise and an infinite cylinder (an ellipsoid with one of its axes tending toward infinity with the other two being the same) which has Template:Math along its axis and Template:Math perpendicular to its axis.^[8] The demagnetizing factors are the principal values of the depolarization tensor, which gives both the internal and external values of the fields induced in ellipsoidal bodies by applied electric or magnetic fields.^{[9] [10] [11]}

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