000			06201cam a2200649Ia 4500
001			ocn927159944
003			OCoLC
005			20190328114813.0
006			m o d
007			cr cnu---unuuu
008			151030s2016 ne ob 001 0 eng d
040			_aIDEBK _beng _epn _cIDEBK _dN$T _dYDXCP _dCDX _dOPELS _dEBLCP _dOCLCF _dOCLCQ _dSTF _dOTZ _dOCLCA _dOCLCQ _dU3W _dD6H _dNLE _dAU@ _dUKMGB _dTKN _dLOA _dCUY _dZCU _dMERUC _dICG _dCOCUF _dVT2 _dDKC
015			_aGBB713059 _2bnb
016	7		_a018186839 _2Uk
019			_a929533124
020			_a0444626395 _q(electronic bk.)
020			_a9780444626394 _q(electronic bk.)
020			_z0444626344
020			_z9780444626349
035			_a(OCoLC)927159944 _z(OCoLC)929533124
050		4	_aQC765
072		7	_aSCI _x038000 _2bisacsh
082	0	4	_a538.4 _223
245	0	0	_aMagnetism of surfaces, interfaces, and nanoscale materials : Vol. 5 / _h[electronic resource] _cedited by Robert E. Camley, Zbigniew Celinski, Robert L. Stamps.
260			_aAmsterdam : _bElsevier, _c�2016.
300			_a1 online resource (x, 466 pages).
336			_atext _btxt _2rdacontent
337			_acomputer _bc _2rdamedia
338			_aonline resource _bcr _2rdacarrier
490	1		_aHandbook of surface science ; _vv. 5
504			_aIncludes bibliographical references and index.
588	0		_aPrint version record.
520			_aIn the past 30 years, magnetic research has been dominated by the question of how surfaces and interfaces influence the magnetic and transport properties of nanostructures, thin films and multilayers. The research has been particularly important in the magnetic recording industry where the giant magnetoresistance effect led to a new generation of storage devices including hand-held memories such as those found in the ipod. More recently, transfer of spin angular momentum across interfaces has opened a new field for high frequency applications. This book gives a comprehensive view of research at the forefront of these fields. The frontier is expanding through dynamic exchange between theory and experiment. Contributions have been chosen to reflect this, giving the reader a unified overview of the topic.
505	0		_a""Front Cover""; ""Magnetism of Surfaces, Interfaces, and Nanoscale Materials""; ""Copyright""; ""Contents""; ""Contributors""; ""Preface""; ""Chapter 1: Growth and Characterization of Magnetic Thin Film and Nanostructures""; ""1. Introduction""; ""2. Thin-Film Growth""; ""2.1. Thermal and Electron Beam Evaporation""; ""2.2. Sputter Deposition""; ""2.2.1. DC Sputter Deposition""; ""2.2.2. RF Sputter Deposition""; ""2.2.3. Magnetron Sputter Deposition""; ""3. Characterization Techniques""; ""3.1. Surface Characterization""; ""3.1.1. Atomic Force Microscopy""
505	8		_a""3.1.2. Magnetic Force Microscopy""""3.2. Static Magnetic Characterization""; ""3.2.1. MOKE Spectroscopy""; ""3.2.2. Vibrating Sample Magnetometry""; ""3.3. Dynamic Magnetic Characterization""; ""3.3.1. FMR Spectroscopy""; ""3.3.2. BLS Spectroscopy""; ""4. Magnetic Nanostructures""; ""4.1. Lithography""; ""4.2. Pattern Transfer""; ""4.3. Practical Examples""; ""4.3.1. Planar Magnetic Nanostructures""; ""4.3.2. Thickness-Modulated Magnetic Nanostructures""; ""4.3.3. Bicomponent Magnetic Nanostructures""; ""5. Conclusion""; ""Acknowledgments""; ""References""
505	8		_a""Chapter 2: Element-Specific Probes of Magnetism""""1. Introduction""; ""2. Fundamental Aspects of Optical Excitation""; ""2.1. Electronic States in Solids""; ""2.2. Spectroscopy of Core States""; ""2.3. X-Ray Photoemission Spectroscopy""; ""2.4. X-Ray Absorption Spectroscopy""; ""2.5. X-Ray Reflection Spectroscopy""; ""3. Spin-Sensitive Photoemission""; ""3.1. Core-Level Photoemission from Ferromagnets""; ""3.1.1. Spin Polarimeter Schemes""; ""3.1.2. 3s XPS""; ""3.1.3. 2p XPS""; ""3.2. Magnetic Dichroism in Photoemission""; ""3.2.1. Magnetic Circular Dichroism in Photoemission""
505	8		_a""3.2.2. Role of Angular Selection in Photoemission""""4. Magnetic Dichroism in X-Ray Absorption""; ""4.1. Magnetic X-Ray Circular Dichroism""; ""4.2. Magnetic X-Ray Linear Dichroism""; ""4.3. Hybrid Systems""; ""5. Magnetic Resonant X-Ray Scattering""; ""5.1. Basic Aspects""; ""5.2. Complex Layered Structures""; ""5.3. Antiferromagnets""; ""6. Addressing Picosecond Magnetization Dynamics""; ""7. Ultrafast Demagnetization Dynamics""; ""8. Summary and Conclusions""; ""Acknowledgments""; ""References""; ""Chapter 3: Magnetization Dynamics""; ""1. Introduction""; ""2. Analytic Results""
505	8		_a""2.1. Infinitely Extended Flat Plate: In-Plane Field""""2.2. Spin Waves Propagating Perpendicular to the Surface, Conducting Films""; ""2.3. Surface Modes for Spin Waves Propagating Parallel to the Film Surface""; ""2.4. Infinitely Extended Flat Plate-Perpendicular-to-Plane Magnetization""; ""2.5. Nanostructures""; ""2.6. Antiferromagnets""; ""3. Examples of Experimental Characterization of Ferromagnetic Samples""; ""4. FMR Techniques""; ""4.1. Magnetic Damping""; ""4.2. Broadband FMR-Frequency Swept""; ""4.3. Broadband FMR-Field Swept""; ""4.3.1. Multimode Cavity Configuration""
650		0	_aMagnetic materials.
650		0	_aThin films _xSurfaces _xMagnetic properties.
650		0	_aInterfaces (Physical sciences)
650		7	_aSCIENCE _xPhysics _xMagnetism. _2bisacsh
650		7	_aInterfaces (Physical sciences) _2fast _0(OCoLC)fst00976205
650		7	_aMagnetic materials. _2fast _0(OCoLC)fst01005731
650		7	_aThin films _xSurfaces _xMagnetic properties. _2fast _0(OCoLC)fst01150041
650		7	_aElectrical Engineering. _2hilcc
650		7	_aElectrical & Computer Engineering. _2hilcc
650		7	_aEngineering & Applied Sciences. _2hilcc
655		4	_aElectronic books.
655		7	_aElectronic books. _2lcgft
700	1		_aCamley, Robert E.
700	1		_aCelinski, Zbigniew.
700	1		_aStamps, Robert L.
776	0	8	_iPrint version: _aCamley, Robert E. _tMagnetism of Surfaces, Interfaces, and Nanoscale Materials. _dSaint Louis : Elsevier Science, �2015
830		0	_aHandbook of surface science ; _vv. 5.
856	4	0	_3ScienceDirect _uhttp://www.sciencedirect.com/science/book/9780444626349
999			_c247204 _d247204