光电子光谱学原理和应用(Photoelectron spectroscopy),第3版

光电子谱技术是研究原子、分子、固体和表面电子结构的一种非常有效的手段。本书全面系统地介绍了光电子谱技术的原理和应用，并简明讨论了逆光发射、自旋极化光发射和光电子衍射等现象。本书是一本非常实用的光电子谱技术的专著，内容几乎覆盖了光电子研究的所有领域。其特点是紧密联系实验，并利用理论详细解释实验结果，达到理论和应用的有机结合。书中还收集了大量的实际材料的光电子谱分析，同时给出了大量的实验数据，以便于读者的查阅。总之，该书既是一本很有价值的参考书，又可作为初学者的入门教材。 　　 &H$ 3`"p5u  
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作者在该领域做出了杰出的贡献。在第3版中，作者介绍了大量最新研究成果，并对光电子谱技术很多方面给出了有深刻见解的讨论。 　　 K#H}=Y A  
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读者对象：适用于凝聚态物理学、材料物理学和光电子学等专业的高年级本科生、研究生和相关专业的科研人员。  XWV)   
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目录 e  p~3e5  
1． Introduction and Basic Principles -v.\CtpHv  
1．1 Historical Development 34k<7X`I  
1．2 The Electron Mean Free Path B~QX{  
1．3 Photoelectron Spectroscopy and Inverse Photoelectron Spectroscopy b|U&{I>TH  
1．4 Experimental Aspects CdgZq\  
1．5 Very High Resolution 2ikY
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1．6 The Theory of Photoemission ce th)Xm  
1．6．1 Core-Level Photoemission _"_ W KlN  
1．6．2 Valence-State Photoemission _" W<>  
1．6．3 Three-Step and One-Step Considerations "-GjwB  
1．7 Deviations from the Simple Theory of Photoemission GY,l&.&  
References 'uS!rKkQlu  
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2． Core Levels and Final States JUXIE y^  
2．1 Core-Level Binding Energies in Atoms and Molecules n#t{3qzpD  
2．1．1 The Equivalent-Core Approximation MEMD8:['  
2．1．2 Chemical Shifts Nl3x BM%  
2．2 Core-Level Binding Energies in Solids 8rwkux >  
2．2．1 The Born-Haber Cycle in Insulators 4wh_iO  
2．2．2 Theory of Binding Energies sE@t$'=  
2．2．3 Determination of Binding Energies and Chemical Shifts from Thermodynamic Data &cztUM(  
2．3 Core Polarization j@1cllJkh  
2．4 Final-State Multiplets in Rare-Earth Valence Bands ["|AD,$%  
2．5 Vibrational Side Bands q+f]E&':  
2．6 Core Levels of Adsorbed Molecules yG|^
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2．7 Quantitative Chemical Analysis from Core-Level Intensities S%gb1's  
References i <0H W  
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3． Charge-Excitation Final States: Satellites xO)vn\uJ  
3．1 Copper Dihalides; 3d Transition Metal Compounds jjbBv~vs  
3．1．1 Characterization of a Satellite LWE[]1=  
3．1．2 Analysis of Charge-Transfer Satellites H6(kxpOI\  
3．1．3 Non-local Screening ^N}zePy0  
3．2 The 6-eV Satellite in Nickel B2t.;uz(,  
3．2．1 Resonance Photoemission ga&l.:lo  
3．2．2 Satellites in Other Metals :=vB|Ch:~  
3．3 The Gunnarsson-Sch6nhammer Theory JF!?i6V  
3．4 Photoemission Signals and Narrow Bands in Metals *5Upb,**  
References Ry>c]\a]  
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4． Continuous Satellites and Plasmon Satellites: XPS Photoemission in Nearly Free Electron Systems 7^,C=2  
4．1 Theory ktLXL;~X  
4．1．1 General +^tq?PfE  
4．1．2 Core-Line Shape yL/EIN  
4．1．3 Intrinsic Plasmons >yFEUD:  
4．1．4 Fxtrinsic FAectron Scattering: Plasmons and Background d2lOx|jt  
4．1．5 The Total Photoelectron Spectrum meunAEe  
4．2 Experimental Results k%-_z}:3V  
4．2．1 The Core Line Without Plasmons AujvKQ(  
4．2．2 Core-Level Spectra Including Plasmoas %"^$$$6%  
4．2．3 Valence-Band Spectra of the Simple Metals uU(G&:@  
4．2．4 Simple Metals: A General Comment U;Z6o1G  
4．3 The Background Correction U">J$M@  
References RK?b/9y  
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5． Valence Orbitals in Simple Molecules and Insulating Solids ModwJ w  
5．1 UPS Spectra of Monatomic Gases <![tn#_  
5．2 Photoelectron Spectra of Diatomic Molecules jqxeON  
5．3 Binding Energy of the H2 Molecule WmU4~.  
5．4 Hydrides Isoelectronic with Noble Gases dA>=#/"  
Neon (Ne) :q=u+h_  
Hydrogen Fluoride (HF) (\m4o   
Water (H2O) f1MKYM%^x  
Ammonia (NH3) l'=H,8LfA  
Methane (CH4) eq.K77El{J  
5．5 Spectra of the Alkali HMides *Wk y#  
5．6 Transition Metal Dihalides *KNj5>6=  
5．7 Hydrocarbons gX<"-,5jc  
5．7．1 Guidelines for the Interpretation of Spectra from Free Molecules Sx)b~*  
5．7．2 Linear Polymers yoa"21E$  
5．8 Insulating Solids with Valence d Electrons `<&RZB2  
5．8．1 The NiO Problem Jj+|>(P  
5．8．2 Mort Insulation usEdp  
5．8．3 The Metal-Insulator Transition；the Ratio of the Correlation Energy and the Bandwidth；Doping cF!ygz//  
5．8．4Band Structures of Transition Metal Compounds Nq'Cuwsp  
5．9 High—Temperature Superconductors h(]aP<49L  
5．9．1valence-Band Electronic Structure；Polycrystalline Samples 2[f8"'lUQ  
5．9．2 Dispersion Relations in High Temperature Superconductors；Single Crystals H59}d oKH  
5．9．3 The Superconducting Gap +c4]}9f!  
5．9．4 Symmetry of the Order Parameter in the High-Temperature SuDerconductors y<mmv~=  
5．9．5 Core—Level Shifts }~pT saw  
5．10 The Fermi Liquid and the Luttinger Liquid e! V`cg0  
5．11 Adsorbed Molecules ~]f+  
5．11．1 Outline y1R53u`;L  
5．11．2 CO on Metal Surfaces qN((Xz+AZE  
References 3wZA,Z  
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6．Photoemission of Valence Electrons froill Metallic Solids in the OHe-Electron Approximation S@i*+&Ot  
6．1 Theory of Photoemission：A Summary of the Three-Step Model oC0K!{R*  
6．2 Discussion of the Photocurrent L,#ij!txS  
6．2．1 Kinematics of Internal Photoemission in a Polycrystalline Sample ~EJVlji  
6．2．2 Primary and Secondary Cones in the Photoemission from a Real Solid gwE#,OY*  
6．2．3 Angle-Integrated and Angle-Resolved Data Collection !G E-5\*  
6．3 Photoemission from the Semi—infinite Crystal：The Inverse LEED Formalism X,VOKj.%  
6．3．1 Band Structure Regime zf-)c1$*r  
6．3．2 XPS Regime gyi<ot;  
6．3．3 Surface Emission _kUf[&  
6．3．4 One-Step Calculations ozN#LIM>P  
6．4 Thermal Effects >DX\^86x  
6．5 Dipole Selection Rules for Direct Optical Transitions #T<<{ RA  
References d|5V"U]W;  
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7．Band Structtire and Angular-Resolved Photoelectron Spectra Z)E[Bv=  
7．1 Free-Electron Final—State Model ZuZe8&  
7．2 Methods Employing Calculated Band Structures %oVoE2T{@  
7．3 Methods for the Absolute Determination of the Crystal Momentum bOR1V\Jr$q  
7．3．1 Triangulation or Energy Coincidence Method gP=(2EVE  
7．3．2 Bragg Plane Method: Variation of External Emission Angle at Fixed Photon Frequency (Disappearance/Appearance Angle Method fNb2>1  
7．3．3 Bragg Plane Method: Variation of Photon Energy at Fixed Emission Angle (Symmetry Method) L=Cm0q 3v  
7．3．4 The Surface Emission Method and Electron Damping H9'Y` -r  
7．3．5 The Very-Low-Energy Electron Diffraction Method gBM6{48GF  
7．3．6 The Fermi Surface Method ;Zfglid  
7．3．7 Intensities and Their Use in Band-Structure Determinations 7"}<J7"})  
7．3．8 Summary =7%1]  
7．4 Experimental Band Structures I2G4j/c=z  
7．4．1 One- and Two-Dimensional Systems Jlgo@?Lc  
7．4．2 Three-Dimensional Solids: Metals and Semiconductors SF$'$6x}  
7．．4．3UPS Band Structures and XPS Density of States Vk%[N>  
7．5 A Comment QC@nRy8%  
References yVA<-PlS<  
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8．Surface States, Surface Effects bvdAOvxChW  
8．1 Theoretical Considerations ?kBi9^
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8．2 Experimental Results on Surface States .xJW=G{/  
8．3 Quantum-Well States cQkH4>C~  
8．4 Surface Core-Level Shifts #$q~ZKB  
References Gvg)@VNr  
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9．Inverse Photoelectron Spectroscopy m$nT#@l5bH  
9．1 Surface States OO)m{5r,{  
9．2 Bulk Band Structures kmHIU}Z  
9．3 Adsorbed Molecules :4 9ttJl  
References #H9J/k_  
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10． Spin-Polarized Photoelectron Spectroscopy ut26sg{s(  
10．1 General Description rv`kP"I  
10．2 Examples of Spin-Polarized Photoelectron Spectroscopy pfd||Z  
10．3 Magnetic Dichroism #1-y[w/  
References 3GMRH;/w  
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11． Photoelectron Diffraction o$dnp`E  
11．1 Examples CX](^yU_  
11．2 Substrate Photoelectron Diffraction E]G#"EV!Y  
11．3 Adsorbate Photoelectron Diffraction ]ZJu  
11．4 Fermi Surface Scans :e9}k5kdk  
References ^`0^|u=  
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Appendix 3SbtN3  
A．1 Table of Binding Energies #"tHT<8u  
A．2 Surface and Bulk Brillouin Zones of the Three Low-Index Faces of a Face—Centered Cubic(fcc)Crystal Face MUo}Qi0K  
A．3 Compilation of Work Functions o`B,Pt5vu  
References 34Q;& z\e  
Index