Structural and Magnetic Phase Transitions in MineralsS. Ghose, J.M.D. Coey, E. Salje This volume in Advances in Physical Geochemistry presents the latest synthesis of theory and experimental data pertaining to structural and magnetic phase transitions in a variety of geochemically important minerals. The book is the first to cover the impact of this rapidly progressing area of solid state physics in earth sciences and reflects its growing significance for mineralogy and petrology. |
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Page 163
... anisotropy . Magnetocrystalline anisotropy is important in silicates containing ions like Fe2 * , which have some residual orbital moment , but the influence of the crystal field is negligible on S - state ions such as Fe3 * or Mn2 ...
... anisotropy . Magnetocrystalline anisotropy is important in silicates containing ions like Fe2 * , which have some residual orbital moment , but the influence of the crystal field is negligible on S - state ions such as Fe3 * or Mn2 ...
Page 200
... anisotropy in M1 explains the canting . As for the a direction chosen by the G modes in Mn2SiO4 , our computations have shown that it is not due to the dipolar interactions between the magnetic moments , which would favor the b axis ...
... anisotropy in M1 explains the canting . As for the a direction chosen by the G modes in Mn2SiO4 , our computations have shown that it is not due to the dipolar interactions between the magnetic moments , which would favor the b axis ...
Page 204
... anisotropy of the Mn2 + ions , for x = 0.29 , a = c . For this composition the Fe2 + ions occupy the M1 site more than the M2 site , and the easy axis of the moments on M1 is expected to govern the overall anisotropy . Therefore , this ...
... anisotropy of the Mn2 + ions , for x = 0.29 , a = c . For this composition the Fe2 + ions occupy the M1 site more than the M2 site , and the easy axis of the moments on M1 is expected to govern the overall anisotropy . Therefore , this ...
Contents
Preface | 1 |
Incommensurate Phase Transitions in Quartz and Berlinite | 17 |
Phase Separation in Quadrilateral Pyroxenes and Olivines | 39 |
Copyright | |
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Other editions - View all
Structural and Magnetic Phase Transitions in Minerals S. Ghose,J.M.D. Coey,E. Salje Limited preview - 2012 |
Structural and Magnetic Phase Transitions in Minerals S. Ghose,J.M.D. Coey,E. Salje Snippet view - 1988 |
Common terms and phrases
a-ẞ transition anisotropy ANNNI model antiferromagnetic atoms axis Bachheimer Ballet behavior berlinite Bukowinski calculated canting cation distributions Chem chemical cluster Co₂SiO4 Coey components composition coupling crystal field crystal structure crystallographic decreases density disordered Dolino Earth Planet electron entropy equilibrium experimental Fe² Fe2+ Fe2SiO4 Fe³ feldspar ferromagnetic free energy Fuess Geophys Ghose grunerite high-spin ilvaite inc phase incommensurate phase interactions ions Jeanloz Landau theory lattice layers Lindsley long-range order low temperatures lower mantle LS transition M2 sites magnetic order Magnetic properties magnetic structure Matsui measurements MgSiO3 Mineral Mn2SiO4 Mössbauer neutron diffraction observed octahedral olivines orbital order parameter orthopyroxene orthorhombic oxides pairs perovskite phase diagrams phase transition Phys polytypes polytypic phases predicted pyroxenes quartz Salje sample shown in Fig silicates SiO2 solid solutions space group spin glass ẞ phase susceptibility symmetry temperature dependence thermal expansion thermodynamic tion transformation X-ray zero pressure