Preface
Contents
Contributors
Part I: General Introduction
Chapter 1: General introduction
1.1 Motivation
1.2 Theoretical Foundations and Simulation of Surface Structures
1.3 Surface Reconstruction and Relaxation
1.4 Structural Defects at Surfaces
1.5 Photoelectron Spectroscopies Applied to Condensed Matter Systems
1.6 Raman Scattering at Surfaces
1.7 Field Electron and Ion Emission: Basic Formulae and Constants
1.8 Epigraphene
1.9 Fullerenes on Surfaces
1.10 Surfaces at Metal-Electrolyte Interfaces
Part II: Theoretical Foundations and Simulation of Surface Structures
Chapter 2: Introduction to basic principles of surface structure theoretical simulation
References
Chapter 3: Physics mechanisms of the surface structure formation
References
Chapter 4: Compilation of the theoretical frameworks for surface structure simulations
References
Chapter 5: Determination of the total energy of a many-particle system
5.1 Parametrized Force Fields
5.2 Empirical Tight-Binding Methods
5.3 Hartree-Fock Approximation
5.4 Density-Functional Theory
5.5 Quantum Monte Carlo
5.6 Random-Phase Approximation Total Energy
References
Chapter 6: Basic numerical approaches for surface structure simulation
References
Chapter 7: Comparing theoretically simulated and experimentally determined surface structures
References
Chapter 8: Application to prototypical homopolar semiconductor clean surfaces
8.1 The Si(111) 2 x 1 Pandey Reconstruction
8.2 The Si(111) 7 x 7 DAS Structure
8.3 Ge(111) 2 x 1 and c(2 x 8) Reconstructions
References
Chapter 9: Application to prototypical heteropolar semiconductor clean surfaces
9.1 Cleaved Nonpolar Surfaces of Ionic Semiconductors and Oxides: GaAs(110) 1 x 1 Bond Rotation Relaxation Model as an Example
9.2 Polar Surfaces of Ionic Materials: GaAs(100) Surface Stoichiometry and Structure
References
Chapter 10: Application to prototypical metal clean surfaces: the Au(110) 1 x 2 missing-row structure
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Chapter 11: Application to prototypical metal-oxide clean surfaces: the complex TiO2 (110) surface reconstruction
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Chapter 12: Conclusions about theoretical foundations and simulation of surface structures
Part III: Surface Reconstruction and Relaxation
Chapter 13: Introduction to surface reconstruction and relaxation
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Chapter 14: Clean surfaces of semiconductors: introductory remarks
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Chapter 15: Homopolar cubic semiconductors: clean diamond surfaces C(100), C(110), and C(111)
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Chapter 16: Homopolar cubic semiconductors: clean silicon surfaces Si(100), Si(110), and Si(111)
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Chapter 17: Homopolar cubic semiconductors: clean germanium surfaces Ge(100), Ge(110), and Ge(111)
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Chapter 18: Heteropolar cubic semiconductors: low-index surfaces of zinc blend compound semiconductors
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Chapter 19: Heteropolar Wurtzite type semiconductors
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Chapter 20: Clean surfaces of oxides: introductory remarks
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Chapter 21: Clean surfaces of titanium dioxide TiO2 and other rutile structures
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Chapter 22: Clean surfaces of zinc oxide and other Wurtzite type structures
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Chapter 23: Clean surfaces of rock salt oxides
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Chapter 24: Clean surfaces of perovskites
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Chapter 25: Clean surfaces of corundum oxides and similar
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Chapter 26: Clean surfaces of calcite-form oxides
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Chapter 27: Clean surfaces of metals: introductory remarks
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Chapter 28: Relaxation of the clean surfaces of metals
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Chapter 29: Reconstruction at the clean surfaces of metals
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Part IV: Structural Defects at Surfaces
Chapter 30: Introduction to structural defects at surfaces
30.1 Preliminary Remarks
30.2 Point Defects
30.3 Line Defects
30.4 Experimental Techniques to Probe Structural Surface Defects
30.5 Scanning Probe Microscopy
30.6 Other Microscopy Techniques
30.7 Surface Diffraction
30.8 Ion Scattering
30.9 Other Techniques
30.10 Presentation of the Data Section
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Chapter 31: Structure of domain boundaries: metals: Au
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Chapter 32: Structure of domain boundaries: metals: Fe
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Chapter 33: Structure of domain boundaries: metals: Ga
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Chapter 34: Structure of domain boundaries: metals: Ir
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Chapter 35: Structure of domain boundaries: metals: Pt
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Chapter 36: Structure of domain boundaries: metals: W
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Chapter 37: Structure of domain boundaries: group IV elements and IV-IV compounds: diamond
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Chapter 38: Structure of domain boundaries: group IV elements and IV-IV compounds: Si
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Chapter 39: Structure of domain boundaries: group IV elements and IV-IV compounds: Ge
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Chapter 40: Structure of domain boundaries: group IV elements and IV-IV compounds: SiC
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Chapter 41: Structure of domain boundaries: group III-V compounds: GaAs
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Chapter 42: Structure of domain boundaries: other III-V compounds: GaP, GaSb, InAs, InP, InSb
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Chapter 43: Structure of domain boundaries: II-VI compounds: CdTe, HgTe
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Chapter 44: Structure of domain boundaries: binary oxides: Al2O3
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Chapter 45: Structure of domain boundaries: binary oxides: Al2O3 films
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Chapter 46: Structure of domain boundaries: binary oxides: Fe3O4
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Chapter 47: Structure of domain boundaries: binary oxides: Fe3O4 films on MgO(001)
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Chapter 48: Structure of domain boundaries: binary oxides: TiO2 (anatase)
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Chapter 49: Structure of domain boundaries: binary oxides: TiO2 (rutile)
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Chapter 50: Structure of domain boundaries: other binary oxides: SiO2, SnO2, and WO3
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Chapter 51: Structure of domain boundaries: ternary oxides: titanates (BaTiO3, SrTiO3)
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Chapter 52: Decoration of domain boundaries: metals: Au (decoration by metals)
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Chapter 53: Decoration of domain boundaries: metals: Au (decoration by molecules)
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Chapter 54: Decoration of domain boundaries - group IV elements and IV-IV compounds - Si (001)
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Chapter 55: Decoration of domain boundaries: group IV elements and IV-IV compounds: Si (111) (decoration by elemental metals a...
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Chapter 56: Decoration of domain boundaries: group IV elements and IV-IV compounds: Si(111) (decoration by compounds)
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Chapter 57: Decoration of domain boundaries: group IV elements and IV-IV compounds: Si(111) (decoration by molecules)
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Chapter 58: Decoration of domain boundaries: group IV elements and IV-IV compounds: other Si surfaces
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Chapter 59: Decoration of domain boundaries: group IV elements and IV-IV compounds: Ge
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Chapter 60: Decoration of domain boundaries: group IV elements and IV-IV compounds: SiC
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Chapter 61: Decoration of domain boundaries: group III-V compounds: InSb
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Chapter 62: Decoration of domain boundaries: binary oxides: Al2O3
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Chapter 63: Decoration of domain boundaries: binary oxides: Al2O3 films
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Chapter 64: Decoration of domain boundaries: binary oxides: Fe3O4
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Chapter 65: Decoration of domain boundaries: binary oxides: TiO2
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Chapter 66: Decoration of domain boundaries: ternary oxides: SrTiO3
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Chapter 67: Coexistence of domains: metals: Au
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Chapter 68: Coexistence of domains: metals: other metals (Ir, Pt, W)
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Chapter 69: Coexistence of domains: group IV elements and IV-IV compounds: diamond
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Chapter 70: Coexistence of domains: group IV elements and IV-IV compounds: Si
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Chapter 71: Coexistence of domains: group IV elements and IV-IV compounds: Ge
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Chapter 72: Coexistence of domains: group III-V compounds: GaAs
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Chapter 73: Coexistence of domains: other III-V compounds and II-VI compounds (AlSb, GaP, GaSb, InAs, InP, InSb, CdTe)
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Chapter 74: Coexistence of domains: binary oxides: Al2O3
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Chapter 75: Coexistence of domains: binary oxides: TiO2
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Chapter 76: Coexistence of domains: other binary oxides (Ce7O11, Fe3O4, Fe3O4/MgO, SnO2, WO3)
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Chapter 77: Coexistence of domains: ternary oxides: BaTiO3
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Chapter 78: Coexistence of domains: ternary oxides: SrTiO3
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Chapter 79: Phase transition: metals: Au
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Chapter 80: Phase transition: metals: Ga
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Chapter 81: Phase transition: metals: Ir
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Chapter 82: Phase transition: metals: Mo
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Chapter 83: Phase transition: metals: Pt
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Chapter 84: Phase transition: metals: W
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Chapter 85: Phase transition: group IV elements and IV-IV compounds: diamond
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Chapter 86: Phase transition: group IV elements and IV-IV compounds: Si
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Chapter 87: Phase transition: group IV elements and IV-IV compounds: Ge
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Chapter 88: Phase transition: group IV elements and IV-IV compounds: SiC
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Part V: Photoelectron Spectroscopies Applied to Condensed Matter Systems
Chapter 89: Historical remarks and introduction to photoemission
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Chapter 90: The photoemission process
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Chapter 91: Inverse photoemission
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Chapter 92: Spin-polarized photoemission
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Chapter 93: Two-photon photoemission
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Chapter 94: Core-level excitation and related resonant phenomena
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Chapter 95: Escape depth of the photoelectrons
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Chapter 96: Electronic structure in the surface region: bulk and surface states
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Chapter 97: Electronic structure in the surface region: Shockley surface states and image states
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Chapter 98: Electronic structure in the surface region: the Rashba effect and surface states
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Chapter 99: Electronic structure in the surface region: quantum well states
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Chapter 100: Electronic structure in the surface region: electron-boson coupling in metallic systems
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Chapter 101: The common crystal structures
101.1 Face-Centered Cubic
101.2 Body-Centered Cubic
101.3 Hexagonal Close-Packed Structure
Chapter 102: Electronic structure studies of Be (beryllium)
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Chapter 103: Electronic structure studies of C (carbon)
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Chapter 104: Electronic structure studies of Mg (magnesium)
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Chapter 105: Electronic structure studies of Si (silicon)
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Chapter 106: Electronic structure studies of V (vanadium)
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Chapter 107: Electronic structure studies of Cr (chromium)
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Chapter 108: Electronic structure studies of Fe (iron)
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Chapter 109: Electronic structure studies of Ni (nickel)
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Chapter 110: Electronic structure studies of Cu (copper)
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Chapter 111: Electronic structure studies of Ga (gallium) and related compounds: the case of GaN
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Chapter 112: Electronic structure studies of Ge (germanium)
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Chapter 113: Electronic structure studies of Nb (niobium)
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Chapter 114: Electronic structure studies of Mo (molybdenum)
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Chapter 115: Electronic structure studies of Pd (palladium)
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Chapter 116: Electronic structure studies of Ag (silver)
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Chapter 117: Electronic structure studies of W (tungsten)
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Chapter 118: Electronic structure studies of Ir (iridium)
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Chapter 119: Electronic structure studies of Pt (platinum)
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Chapter 120: Electronic structure studies of Au (gold)
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Chapter 121: Electronic structure studies of Pb (lead)
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Chapter 122: Electronic structure studies of Bi (bismuth)
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Chapter 123: Electronic structure studies of Ce (cerium)
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Chapter 124: Electronic structure studies of Gd (gadolinium)
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Chapter 125: Strongly correlated systems: high-Tc superconductors: cuprates
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Chapter 126: (strongly correlated systems): high Tc superconductors: Fe-based
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Chapter 127: Dirac cones and topological states: topological insulators
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Chapter 128: Dirac cones and topological states: Dirac and Weyl semimetals
References
Part VI: Raman Scattering at Surfaces
Chapter 129: Introduction to Raman scattering at surfaces
References
Chapter 130: Fundamentals of surface Raman spectroscopy
References
Chapter 131: Raman selection rules and surface Raman tensor
References
Chapter 132: Surface resonance
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Chapter 133: Historical remarks on surface Raman scattering
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Chapter 134: Clean InP(110)
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Chapter 135: Clean Ge(001)
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Chapter 136: Clean Si(111)
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Chapter 137: Sb monolayer-terminated III-V(110) surfaces
137.1 Structure and Electronic Properties
137.2 Surface Phonons
137.3 Selection Rules
137.4 Surface Resonance
References
Chapter 138: Sb-terminated Si(001) and Ge(001)
References
Chapter 139: As-terminated Si(111)
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Chapter 140: In-terminated Si(111)
140.1 Surface Phonons
140.2 Raman Selection Rules and Surface Resonance
References
Chapter 141: Au-terminated Si(111)
References
Chapter 142: Au-terminated Si(553)
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Chapter 143: Metal surfaces: Si nanoribbons on Ag(110)
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Part VII: Field Electron and Ion Emission: Basic Formulae and Constants
Chapter 144: Introduction to field electron and ion emission and customary units
References
Chapter 145: Basic terminology of Fowler-Nordheim electron transmission theory
References
Chapter 146: Transmission probability for an exactly triangular barrier
References
Chapter 147: Transmission probability for a general rounded barrier
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Chapter 148: The Schottky effect and related parameters
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Chapter 149: Transmission probability for a Schottky-Nordheim barrier
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Chapter 150: Local emission current density regimes
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Chapter 151: Local emission current densities for a Schottky-Nordheim barrier
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Chapter 152: Energy distributions for the Schottky-Nordheim barrier
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Chapter 153: Basic auxiliary relationships
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Chapter 154: Field electron emission measurement circuit theory
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Chapter 155: Basic theory of Fowler-Nordheim plots
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Chapter 156: Testing for lack of field emission orthodoxy
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Chapter 157: Theoretical introduction to field evaporation
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Chapter 158: The prediction of zero-barrier evaporation field
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Chapter 159: Post-field ionization
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Chapter 160: The ``changeover field´´ in thermal-field shaping
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Chapter 161: The position of the electrical surface
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Chapter 162: Physical properties of the noble operating gases
References
Chapter 163: Field calibration issues
163.1 Introduction
163.2 The Sakurai-Müller Approach
163.3 Calibration via Post-Field-Ionization
References
Part VIII: Epigraphene
Chapter 164: Introduction to epigraphene and overview
164.1 Epitaxial Graphene and Transferred Graphene
164.2 Definition of Graphene
164.3 Graphite, Freely Suspended Graphene, and Graphene Isolated on Substrates
164.4 Conclusion
References
Chapter 165: The electronic band structure of graphene
165.1 Tight Binding: Graphene
165.2 Tight Binding: Graphite
165.3 Ab Initio Methods
165.4 Relativistic Interpretation
165.5 Physics Near the K Point
165.6 Influence of the Substrate: Epitaxial Graphene
165.7 Role of Stacking: Multilayer Epitaxial Graphene
165.8 Influence of Substrate: Transferred Graphene
165.9 Graphene Nanostructures
References
Chapter 166: Silicon carbide and epitaxial graphene on silicon carbide
166.1 G.E Acheson: Silicon Carbide, Graphite, and Graphene
166.2 Electronic-Grade Silicon Carbide
166.3 Epitaxial Graphene Growth by Silicon Sublimation
166.4 Confinement Controlled Sublimation (CCS)
166.5 Growth in Ar Atmosphere (Edison Light Bulb Method)
References
Chapter 167: Structure and band structure of epitaxial graphene on hexagonal silicon carbide
167.1 Si-Face
167.2 Buffer Layer
167.3 Growth Mechanism on the Si-Face
167.4 C-Face
167.5 Epigraphene Microstructure on the C-Face
167.6 Epigraphene Growth on the C-Face
167.7 Rotational Stacking on the C-Face
167.8 Epigraphene Electronic Structure on the C-Face
167.9 Raman Spectroscopy: Thickness Determination
167.10 Epigraphene on Other Faces
167.11 Epigraphene on 3C-SiC
167.12 Nanostructured Graphene
167.13 Armchair-Edge Sidewall Ribbons
167.14 Zigzag-Edge Sidewall Ribbons
References
Chapter 168: Electronic transport properties of epigraphene
168.1 Charge Density
168.2 Square Resistance, Mobility, and Charge Density in Single Layers
168.3 Charge Density and Mobility in Multilayers
168.4 Scattering at SiC Steps: The Si-face
168.5 High Current Carrying Capability
References
Chapter 169: Transport properties of epigraphene in magnetic field
169.1 Low-Field (Anti)-weak Localization
169.2 Landau Level Spectroscopy on the C-Face
169.3 High-Field Shubnikov-de Haas Oscillation and Quantum Hall Effect
References
Chapter 170: Towards electronic devices based on epigraphene
170.1 High-Frequency Transistors
170.2 Spintronics
170.3 Large-Scale Integration: Integration with Si
170.4 Bandgap
170.5 Sidewall Ribbons
References
Chapter 171: Optical and plasmonic properties of epigraphene
171.1 Ultrafast Optical Spectroscopy
171.2 THz Generation
171.3 Photocurrent
171.4 Plasmonics
References
Part IX: Fullerenes on Surfaces
Chapter 172: Introduction to fullerenes on surfaces
References
Chapter 173: Band dispersion of solid C60
References
Chapter 174: Fullerenes on metals and semiconductors: interaction with the substrate
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Chapter 175: Ordered fullerenes on metal surfaces: monatomic steps on vicinal surfaces and reconstruction on metals
References
Chapter 176: C60 monolayer on semiconductors
References
Chapter 177: Directing fullerene adsorption via supramolecular templates
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Chapter 178: Co-adsorbed fullerene systems and the formation of heterojunction layers at a nanometer scale
References
Part X: Surfaces at Metal-Electrolyte Interfaces
Chapter 179: Introduction to surfaces at metal-electrolyte interfaces
179.1 Concepts: Properties of Electrolytes
179.2 Concepts: Adsorption-Desorption
179.3 Concepts: The Electrochemical Double Layer
179.4 Concepts: Structure of the Metal Surface
179.5 Models: The Helmholtz Model
179.6 Models: The Gouy-Chapman Model
179.7 Models: The Gouy-Chapman-Stern-Grahame Model
179.8 Methods: General Remarks
179.9 Methods: InSitu
179.10 Methods: ExSitu
179.11 Methods: Theory and Simulations
179.12 Methods: Sample Preparation by Flame Annealing
179.13 Methods: Sample Preparation by Electrochemical Etching and Annealing
179.14 Methods: Sample Preparation by UHV-EC Transfer
179.15 Concluding Remarks
References
Chapter 180: Anion interaction with copper surfaces: general properties of metal surfaces
References
Chapter 181: Hydrohalic acid interaction with copper surfaces: adsorption of halide anions
Chapter 182: Hydrohalic acid interaction with copper surfaces: Cu(100) - chloride and bromide
References
Chapter 183: Hydrohalic acid interaction with copper surfaces: Cu(100) - iodide
References
Chapter 184: Hydrohalic acid interaction with copper surfaces: XRD of chloride, bromide, and iodide on Cu(100)
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Chapter 185: Hydrohalic acid interaction with copper surfaces: Cu(111) - chloride
References
Chapter 186: Hydrohalic acid interaction with copper surfaces: Cu(111) - bromide
References
Chapter 187: Hydrohalic acid interaction with copper surfaces: Cu(111) - iodide
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Chapter 188: Hydrohalic acid interaction with copper surfaces: Cu(110) - bromide
References
Chapter 189: Hydrohalic acid interaction with copper surfaces: Cu(110) - chloride
References
Chapter 190: Hydrohalic acids interaction with copper surfaces: CuI compound formation
References
Chapter 191: Hydrohalic acids interaction with copper surfaces: XPS of Cu(111) - iodide interaction
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Chapter 192: Copper surfaces in perchloric acid
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Chapter 193: Copper surfaces in sulfuric acid: sulfate adsorption on Cu(100) and Cu(111)
References
Chapter 194: Copper surfaces in sulfuric acid: sulfate structure on Cu(111)
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Chapter 195: Copper surfaces in sulfuric acid: sulfate adsorption configuration
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Chapter 196: Copper surfaces in sulfuric acid: sulfate-induced surface morphology
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Chapter 197: Copper surfaces in sulfuric acid: sulfate adsorption/desorption kinetics
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Chapter 198: Hydrohalic acid anion interaction with silver surfaces: Ag(100) - chloride
References
Chapter 199: Hydrohalic acid anion interaction with silver surfaces: Ag(100) - bromide
References
Chapter 200: Hydrohalic acid anion interaction with silver surfaces: Ag(100) - iodide
References
Chapter 201: Hydrohalic acid anion interaction with silver surfaces: Ag(111) - chloride
References
Chapter 202: Hydrohalic acid anion interaction with silver surfaces: Ag(111) - bromide
References
Chapter 203: Hydrohalic acid anion interaction with silver surfaces: Ag(111) - iodide
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Chapter 204: Hydrohalic acid anion interaction with silver surfaces: Ag(110) - chloride, bromide, and iodide
References
Chapter 205: Silver surfaces in perchloric acid: Ag(110) - perchlorate
References
Chapter 206: Silver surfaces in sulfuric acid: Ag(100) - sulfate
References
Chapter 207: Silver surfaces in sulfuric acid: Ag(111) - sulfate
References
Chapter 208: Silver surfaces in sulfuric acid: Ag(110) - sulfate
References
Chapter 209: Hydrohalic-acid anion interaction with gold surfaces: Au(100) - chloride
References
Chapter 210: Hydrohalic-acid anion interaction with gold surfaces: Au(100) - bromide
References
Chapter 211: Hydrohalic-acid anion interaction with gold surfaces: Au(100) - iodide
References
Chapter 212: Hydrohalic-acid anion interaction with gold surfaces: Au(111) - chloride
References
Chapter 213: Hydrohalic-acid anion interaction with gold surfaces: Au(111) - bromide
References
Chapter 214: Hydrohalic acid anion interaction with gold surfaces: Au(111) - iodide
References
Chapter 215: Hydrohalic acid anion interaction with gold surfaces: Au(110) - bromide
References
Chapter 216: Hydrohalic acid anion interaction with gold surfaces: Au(110) - iodide
References
Chapter 217: Gold surfaces in perchloric acid: Au(100) - perchlorate
References
Chapter 218: Gold surfaces in perchloric acid: Au(111) - perchlorate
References
Chapter 219: Gold surfaces in perchloric acid: Au(110) - perchlorate
References
Chapter 220: Gold surfaces in sulfuric acid: Au(100) - sulfate
References
Chapter 221: Gold surfaces in sulfuric acid: Au(111) - sulfate
References
Chapter 222: Gold surfaces in sulfuric acid: Au(110) - sulfate
References
Chapter 223: Hydrohalic-acid anion interaction with platinum surfaces: Pt(100) - bromide
References
Chapter 224: Hydrohalic acid anion interaction with platinum surfaces: Pt(100) - iodide
References
Chapter 225: Hydrohalic acid anion interaction with platinum surfaces: Pt(111) - chloride
References
Chapter 226: Hydrohalic acid anion interaction with platinum surfaces: Pt(111) - bromide
References
Chapter 227: Hydrohalic acid anion interaction with platinum surfaces: Pt(111) - iodide
References
Chapter 228: Hydrohalic acid anion interaction with platinum surfaces: Pt(110) - bromide
References
Chapter 229: Hydrohalic acid anion interaction with platinum surfaces: Pt(110) - iodide
References
Chapter 230: Platinum surfaces in perchloric acid: Pt(111), Pt(100), Pt(110) - perchlorate
References
Chapter 231: Platinum surfaces in sulfuric acid: general remarks
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Chapter 232: Platinum surfaces in sulfuric acid: Pt(100) - sulfate
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Chapter 233: Platinum surfaces in sulfuric acid: Pt(111) - sulfate
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