Rayleigh law explained

The Rayleigh law describes the behavior of ferromagnetic materials at low fields.

Ferromagnetic materials consist of magnetic domains. When a small external field

is applied, domains parallel to the external field start to grow. In this region, domain walls are moving. They are hindered by material defects. Lord Rayleigh investigated this first ^[1] and quantified the magnetization

as a linear and quadratic term in the field:

M=\chi₀H+\alpha_R\mu₀H^2.

Here

\chi₀

is the initial susceptibility, describing the reversible part of magnetisation reversal. The Rayleigh constant

\alpha_R

describes the irreversible Barkhausen jumps.

The Rayleigh law was derived theoretically by Louis Néel.,^[2] ^[3]

The same law describes polarization^[4] and direct^[5] and converse^[6] piezoelectric response of some ferroelectric and ferroelectric-ferroelastic materials. The common feature for ferromagnetic, ferroelectric and ferroelastic materials (i.e., ferroic materials) are domains whose boundaries (domain walls) can be moved by magnetic, electric or mechanical fields.

References

Book: Kronmüller. Helmut. Manfred. Fähnle. Micromagnetism and the microstructure of ferromagnetic solids. Cambridge University Press. 2003. 0-521-33135-8. 148.
Book: Cullity. Introduction to magnetic materials. Addison-Wesley. 1972. 342.

Notes and References

Rayleigh. Lord. John William Strutt, 3rd Baron Rayleigh. On the behaviour of iron and steel under the operation of feeble magnetic forces. Philosophical Magazine. 23. 142. 225–248. 1887. 10.1080/14786448708628000. 1941-5982.
Néel. Louis. Louis Néel. Théories des lois d'aimantation de Lord Rayleigh. Cahiers Phys.. 12. 1–20. 1942.
Néel. Louis. Louis Néel. Some theoretical aspects of rock-magnetism. Adv. Phys.. 4. 14. 191–243. 1955. 10.1080/00018735500101204. 1955AdPhy...4..191N .
Turik. A.V.. Theory of polarization and hysteresis of ferroelectrics. Soviet Physics - Solid State. 5. 4. 885–887. 1963.
Damjanovic. D.. Stress and frequency dependence of the direct piezoelectric effect in ferroelectric ceramics. J. Appl. Phys.. 82. 4. 1788–1797. 1997. 1997JAP....82.1788D . 10.1063/1.365981 .
Taylor. D.V.. Damjanovic. D.. Setter. N.. Nava Setter. Nonlinear contributions to dielectric and piezoelectric properties in lead zirconate titanate thin films. Ferroelectrics. 224. 4. 299–306. 1999. 10.1080/00150199908210580. 1999Fer...224..299T .