This paper proposes a mechanism of formation of the magnetic domains on cooling a ferromagnetic material from a higher temperature than the Curie temperature. It is derived from the well-known theory of crystallization in an amorphous material through a two-step mechanism of nucleation and crystal growth. Following this approach it is shown that the domain structure should depend on the free-energy change DeltaG per mole of magnetic moment aligning in the same direction. A method to avoid calculation of DeltaG is shown. This approach was successfully applied to explain the differences between the domain structures of the annealed and the as-quenched samples of the amorphous alloy Fe62.5Co6Ni7.5Zr6Cu1Nb2B15. Moreover, it gives an explanation for recent findings on the magnetic microstructure of high-permeability materials.
A new hypothesis about the mechanism of magnetic-domain formation / Branda, Francesco; Luciani, Giuseppina; Costantini, Aniello. - In: PHILOSOPHICAL MAGAZINE. B, PHYSICS OF CONDENSED MATTER, ELECTRONIC, OPTICAL AND MAGNETIC PROPERTIES. - ISSN 0141-8637. - ELETTRONICO. - 82:(2002), pp. 1859-1865. [10.1080/1364281021000039253]
A new hypothesis about the mechanism of magnetic-domain formation
BRANDA, FRANCESCO;LUCIANI, GIUSEPPINA;COSTANTINI, ANIELLO
2002
Abstract
This paper proposes a mechanism of formation of the magnetic domains on cooling a ferromagnetic material from a higher temperature than the Curie temperature. It is derived from the well-known theory of crystallization in an amorphous material through a two-step mechanism of nucleation and crystal growth. Following this approach it is shown that the domain structure should depend on the free-energy change DeltaG per mole of magnetic moment aligning in the same direction. A method to avoid calculation of DeltaG is shown. This approach was successfully applied to explain the differences between the domain structures of the annealed and the as-quenched samples of the amorphous alloy Fe62.5Co6Ni7.5Zr6Cu1Nb2B15. Moreover, it gives an explanation for recent findings on the magnetic microstructure of high-permeability materials.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
