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The spin resonance condition =H₀{H₀ (2H₄+H₀) }^1{2} previously given by Kittel for a disk-shaped single-domain uniaxial or cubic antiferromagnetic crystal at 0^ with H₀ parallel to the domain axis is extended by classical calculations to cover finite temperature, ellipsoidal shape, orthorhombic symmetry, generalized two-lattice anisotropy, and arbitrary static field direction. The normal precessional modes are discussed. A quantum-mechanical derivation of the resonance equations is carried out by the method developed by Van Vleck for ferromagnetic resonance; no new features are introduced by the quantum-mechanical calculation. Several factors contributing to the line width are considered. Existing experimental data on antiferromagnetic resonance are reviewed; the data are scanty and taken in circumstances not closely related to the situation envisaged by the theory.
Keffer et al. (Tue,) studied this question.
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