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6: Ferromagnetism

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    22831

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    A description of the ferromagnetic state with an application to magnetic recording.

    • 6.1: Introduction to Ferromagnetism
      This page discusses magnetization density (\(\vec M\)) and its relationship with magnetic field (\(\vec H\\)), characterized by magnetic susceptibility (\(\chi\)). In non-magnetic materials, magnetization is minimal, whereas ferromagnetic materials like iron exhibit significant magnetization independent of \(\vec H\) below the Curie Temperature (\(T_c\)).
    • 6.2: B-H Curves
      This page covers the magnetic properties of ferromagnetic materials, focusing on the relationship between magnetic induction and internal fields. It explains magnetization curves, key parameters like remanent and coercive fields, and distinguishes between soft and hard ferromagnets. It also examines crystal structure effects and measurement challenges of these materials, particularly in obtaining intrinsic properties due to demagnetizing factors.
    • 6.3: Digital Magnetic Recording
      This page explains the structure and operation of magnetic hard discs in computer storage, focusing on the thin cobalt alloy coating, the function of the write head with a permalloy yoke, and the magnetization process for data storage. It highlights advanced magnetoresistance technology used for reading data, which results in high storage densities and enhanced performance, illustrated by an IBM hard disc drive example.
    • 6.4: Electromagnets
      This page examines the magnetic field behavior in an electromagnet, specifically focusing on the uniform B-field and the H-field in a ferromagnetic yoke. It establishes the continuity of the B-field across material boundaries using Maxwell's equations and highlights that the H-field in the gap is notably higher than in the yoke due to free space permeability.

    This page titled 6: Ferromagnetism is shared under a CC BY 4.0 license and was authored, remixed, and/or curated by John F. Cochran and Bretislav Heinrich.