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200 00$aMagnetic properties of antiferromagnetic oxide materials$b[electronic resource] $esurfaces, interfaces, and thin films /$fedited by Lamberto Duo?, Marco Finazzi, and Franco Ciccacci
210   $aWeinheim $cWiley-VCH Verlag$d2010
215   $a1 online resource (363 p.)
300   $aDescription based upon print version of record.
311   $a3-527-40881-9 
320   $aIncludes bibliographical references and index.
327   $aMagnetic Properties of Antiferromagnetic Oxide Materials; Contents; 6.5.1.1 The Case of ?af  1; Preface; List of Contributors; 1 Low-Dimensional Antiferromagnetic Oxides : An Overview; 1.1 Introduction; 1.2 Finite-Size Effects on the Magnetic Ordering Temperature; 1.3 AFM Anisotropy; 1.3.1 Magnetocrystal Anisotropy; 1.3.2 Dipolar Anisotropy; 1.4 Interlayer Coupling in AFM-FM Bilayers and Multilayers; 1.4.1 AFM-FM Interface Coupling; 1.4.2 Coupling between FM Layers Separated by an AFM Oxide Spacer; 1.5 Micromagnetic Structure at AFM-FM Interfaces; 1.6 Applications; 1.7 Conclusions; References
327   $a2 Growth of Antiferromagnetic Oxide Thin Films2.1 Introduction; 2.2 Nickel Oxide; 2.2.1 Ultrathin NiO Layers; 2.2.2 Thick NiO Films; 2.3 Cobalt Oxide; 2.3.1 Ultrathin CoO Layers; 2.3.2 Thick CoO Films; 2.4 Other Oxides; 2.4.1 MnO(001); 2.4.2 FeO; 2.4.3 ?-Fe2O3; 2.5 Oxide-Substrate Interface; 2.6 Polar-Oxide Surfaces; 2.7 Conclusions and Perspectives; Acknowledgments; References; 3 Dichroism in X-ray Absorption for the Study of Antiferromagnetic Materials; 3.1 X-ray Absorption and X-ray Dichroism; 3.1.1 X-ray Magnetic Circular Dichroism in the One-Electron Approximation
327   $a3.1.1.1 Spin-Orbit Coupling in the d-Band3.1.1.2 Core-Hole and Other Many-Body Effects; 3.1.2 XMCD in the Strongly Correlated Limit: Multiplet Effects; 3.1.2.1 Ligand Field Atomic Multiplet Calculations; 3.1.2.2 Charge-Transfer Effects; 3.2 Sum Rules for X-ray Dichroism; 3.2.1 Orbital Moment; 3.2.2 Spin Moment; 3.2.3 Sum Rule for Linear Dichroism; 3.3 Experimental Determination of X-ray Absorption; 3.4 Linear X-ray Dichroism in Rare-Earth Compounds; 3.4.1 FexTb1-x Amorphous Thin Films; 3.5 Magnetic Dichroism in TM Oxides; 3.5.1 Magnetic Linear Dichroism in Thin NiO Films on MgO
327   $a3.5.1.1 Calculations3.5.1.2 Sample Preparation; 3.5.1.3 Experiment; 3.5.1.4 Results; 3.6 Conclusions; References; 4 Antiferromagnetic Oxide Films on Nonmagnetic Substrates; 4.1 Introduction; 4.2 Electronic Structure of TM Oxides; 4.2.1 Mott-Hubbard and Charge Transfer Insulators; 4.2.2 Ligand Field Theory; 4.2.2.1 Independent Electron Ligand Field Theory; 4.2.2.2 Multiplet Ligand Field Theory; 4.2.3 Spin-Orbit Coupling in Cubic Symmetry; 4.2.3.1 Single Electron in an Open t2g Shell; 4.2.3.2 d6 and d7 Configurations; 4.3 Magnetic Structure; 4.3.1 Magnetic Ordering of MnO, FeO, CoO and NiO
327   $a4.3.1.1 MnO and NiO4.3.1.2 FeO and CoO; 4.4 X-ray Absorption Spectroscopy; 4.4.1 Magnetic Linear Dichroism; 4.5 Strain; 4.6 Linear Dichroism Results for AF TM Monoxide Layers; 4.6.1 XMLD of Epitaxial NiO(100)/MgO layers; 4.6.2 Ligand-Field-Induced Linear Dichroism in Strained NiO/Ag(100) Layers; 4.6.3 Isotropic XAS of CoO; 4.6.4 Linear Dichroism of Strained CoO Layers; 4.6.5 Spin Alignment in Strained CoO; 4.6.6 Electronic Structure of Strained CoO; 4.6.7 Strain-Induced Linear Dichroism in MnO Layers; 4.7 Conclusions
327   $aAppendix: Polarization and Spin Direction Dependence of the Linear Dichroism in Nonspherical Symmetry
330   $aThis first focused treatment on a hot topic highlights fundamental aspects as well as technological applications arising from a fascinating area of condensed matter physics. The editors have excellent track records and, in light of the broadness of the topic, retain the focus on antiferromagnetic oxides. They thus cover such topics as dichroism in x-ray absorption, non-magnetic substrates, exchange bias, ferromagnetic-antiferromagnetic interface coupling and oxide multilayers, as well as imaging using soft x-ray microscopy. The result is a very timely monograph for solid state physicist
606   $aAntiferromagnetism
606   $aSurfaces (Physics)
615  0$aAntiferromagnetism.
615  0$aSurfaces (Physics)
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200 00$aEarthquakes $erisk, monitoring and research /$fEarl V. Leary, editor
205   $a1st ed.
210   $aNew York $cNova Science$dc2009
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330   $aClose to 75 million people in 39 states face some risk from earthquakes. Seismic hazards are greatest in the western United States, particularly California, Alaska, Washington, Oregon, and Hawaii. The Rocky Mountain region, a portion of the central United States known as the New Madrid Seismic Zone, and portions of the eastern seaboard, particularly South Carolina, also have a relatively high earthquake hazard. Compared to the loss of life in other countries, relatively few Americans have died as a result of earthquakes over the past 100 years. The United States, however, faces the possibility of large economic losses from earthquake damaged buildings and infrastructure.
410  0$aNatural disaster research, prediction and mitigation series.
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606   $aEarthquake resistant design
606   $aEarthquake prediction
615  0$aEarthquake hazard analysis.
615  0$aEarthquakes$xSafety measures.
615  0$aEarthquake resistant design.
615  0$aEarthquake prediction.
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