Spin Density Wave States in Transition Metals
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概要
- 論文の詳細を見る
On the basis of an electronic structure calculation, spin density wave states of fcc Fe and Cr are discussed with particular attention to the difference between them. The wave vector at which the unenhanced spin susceptibility of nonmagnetic fcc Fe or Cr becomes maximum is shown to correspond well to the observed wave vector of spin density wave. It is found that a nesting of the Fermi surface hardly contributes to determining the wave vector of the susceptibility maximum for fcc Fe, which exhibits a remarkable contrast to Cr. Another reasoning of the susceptibility maximum is extended from a real space viewpoint. Difference in characteristics of the spin density wave state between fcc Fe and Cr is further illustrated by the electronic structure calculation of spin density wave states with finite magnetic moments.
- 理論物理学刊行会の論文
- 1991-02-05
著者
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Hirai K
Department Of Physics Nara Medical University
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Hirai Kunitomo
Department Of Physics Nara Medical University
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Hirai Kunitomo
Department Of Physics Faculty Of Science Osaka University
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Hirai Kunitomo
Department of Physics, Nara Medical University
関連論文
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- Total Energy Calculation for Spin-Density-Wave Chromium
- Magnetic Phase Diagrams at Zero Temperature of bcc and fcc Transition Metals
- Real Space Approach to the Electronic Structure of Transition Metals
- Triple-Q and Single-Q States in Antiferromagnetic fcc Transition Metals with the First-Kind Ordering
- Large-Scale KKR Calculation for Metallic Superlattices
- Sinusoidal and Helical Spin Density Wave States in Transition Metals
- Spin Density Wave States in Transition Metals
- Spin-Density-Wave Order and Interlayer Magnetic Coupling in Fe/Cr Superlattices : Condensed Matter: Electronic Properties, etc.
- Electronic Structure of Sinusoidal Spin Density Wave State in Chromium
- Electronic Structure of Helical Spin Density Wave State in fcc Iron
- Unenhanced Spin Susceptibility Consideration of the Spin Density Wave State in fcc Fe