Spin-Polarized Two-Electron Spectroscopy of Surfaces (eBook)

Sergey Samarin graduated from Leningrad State University in 1972 and completed his PhD studies of “radiative interaction of low-energy electrons with metals” in 1976. Then, as Research Fellow, Senior Research Fellow at the Institute of Physics, Leningrad State University (now St. Petersburg State University), he pursued further aspects of electron interactions with surfaces. From 1981-1984, as Associate Professor at the University of Conakry, Guinea, his accomplishments included fluency in French. After returning to St. Petersburg State University he continued his work on low-energy inverse photoemission from solid surfaces, total current spectroscopy, and plasmon excitation in thin Ag films by electron impact with their subsequent decay via photon emission. This work resulted in his Doctor of Science degree in 1995.  From 1991-1992 and 1995-2000 Sergey Samarin enjoyed research as an invited Research Fellow in the group of Professor Kirschner in the Max Planck Institute for Microstructure Physics, Halle, Germany. The development there of low-energy spin-polarized two-electron spectroscopy of solid surfaces in reflection geometry, and its achievements, opened new avenues.   In 2000 he moved to the University of Western Australia, as Research Fellow, Senior Research Fellow, and Research Professor combining his research with undergraduate and graduate teaching. His work was focused mainly on the interaction of spin-polarized low-energy electrons and positrons with solid surfaces for which new instruments were constructed in the Australian Research Council Centre of Excellence for Antimatter and Matter Studies at UWA.  Spin-dependent electron scattering dynamics and spin-related electronic properties of magnetic and nonmagnetic surfaces were studied using spin-polarized low-energy single- and two- electron spectroscopies.  The development of quantum metrology included new technology combining quantum phenomena and a low energy beam of positrons with electrostatic focusing into a UHV surface analysis system.  Recent studies include angular distributions of reemitted positrons from W(100) with over layers of oxygen and LiF as well as reflection and diffraction of low-energy positrons from W(001).  He is now Senior Honorary Research Fellow at the Department of Physics of UWA.Oleg Artamonov graduated from Leningrad State University, Physics Department, in 1959 and began research in the Physics Research Institute, Leningrad State University. In 1968 he presented his PhD thesis concerning the design an electron mirror microscope for visualization of the electrostatic micro-potential of solid surfaces. His pioneering results on electron-photon emission spectroscopy of metals, obtained during 1971-72 at Southampton University, England, as a Research Fellow, were reported at a session of the Royal Physical Society, London. The method of investigation of unoccupied electron states became known as inverse photoemission spectroscopy.Ultra-high-vacuum spherical deflector spectrometer was constructed for secondary electron spectroscopy and for electron energy loss spectroscopy under low-energy electron excitation. Pioneering results showed the dominant role of the long range order of the atomic structure of the surface in the formation of the electron excited states. It was also shown that the energy spectrum of secondary electrons was determined by the surface electron structure, especially the unoccupied electron density of states.Early in the 1980s he suggested coincidence electron spectroscopy as a new method of investigation of the surface electron structure. In collaboration with Prof. J. Kirschner (MPI, Germany) measurements showed for the first time the existence of correlated scattered electrons from a W(100) surfaceIn 1989 at the Freie Univetsitat Berlin with Prof. G. Kaindl the studies of inverse photoemission flourished. His research during 1992-1993 continued with an invitation of the Deutscher Academischer Austauschdienst  on the theme “Role of optical properties of solids in inverse photoemission and bremsstrahlung in plasma resonance region of the medium”. During 1993-1997 further study of electron coincidence spectroscopy continued in the Max-Planck-Institut für Mikrostrukturphysik, Halle, Germany, in Prof. J. Kirschner’s group and subsequently with Prof. G. Stefani, Universitet Roma Tre. After 2002 his collaboration with J. Williams and S. Samarin at the University of Western Australia, led to advances in the field of spin-dependent electron scattering dynamics and coincidence electron spectroscopy of solids. Oleg Mikhailovich Artamonov, Professor at St. Petersburg State University, is a member of the St. Petersburg Physical Society, of Committees of the Institute of Physics.Jim Williams started his scientific research with MSc studies of gas discharges with Professor J Somerville at the University of New England. The nanosecond expansion of electrical sparks revealed hollow conducting regions following an expanding shock wave. Later, at the Australian National University with Professor Noel Dunbar, early studies of nuclear fusion processes involving atomic and molecular hydrogen ion charge exchange collisions earned a PhD in 1965.  The acquisition of low energy electron scattering techniques enabled studies of spin-split excited atomic states at Laval University, Quebec, with Professor Larkin Kerwin from 1965 to 1967.  Subsequently at Gulf General Atomic, San Diego, studies of diagnostics in a nuclear reactor and fusion processes led to threshold resonances in excitation of atomic hydrogen in the laboratory established by W. Fite and R. Stebbings.At Queens University, Belfast, from 1970, many first accurate studies of electron scattering from atomic hydrogen and inert gas atoms provided much data which underpinned the development of quantum scattering approximations and established an academic career with  progression to Reader in 1976. At UWA Perth since 1980 as Professor, and Chair of Physics (1980- 1990), then Winthrop Professor and with the contributions of outstanding colleagues, his career pursued an understanding of quantum phenomena from observations of the structure and dynamics of atoms, molecules, surfaces and thin films.From 1983 polarized electrons and low energy ion and electron spin spectroscopies explored time reversal and geometric asymmetries with two and three particle coincidence detection of photons and electrons. The identification of angular momenta phenomena included spin-orbit and exchange interactions, plasmon effects, and structural and dynamic phase effects in atoms using electron spin and photon polarizations. The outcomes lead, for example, to improved understanding of the mechanism of excitation and ionization processes in atoms. From 2001 he has collaborated with Sergey Samarin on polarised electron and positron studies of surfaces and advancing widespread interests within the Australian Research Council Centre for Antimatter and Matter Studies at UWA.He earned a DSc from ANU (1982) and UWA (2002). In 1989 was awarded the Boas Medal from the Australian Institute of Physics and in 1998 was elected a Fellow of the Australian Academy of Science. Service at UWA included Dean, Faculty of Science, UWA (1992), Head of Division of Agriculture and Science, UWA (1993).  Retirement to Emeritus Professor 2015 and Senior Honorary Research Fellow opened the way for continuing research in quantum aspects of atomic structure and scattering from gaseous and solid materials. 

Preface 6
Contents 9
1 Introduction 12
References 15
2 New Experimental Technique for Studying Electron-Electron Interaction, Electron Correlation, Mechanism of Electron Emission and Electronic Properties of Surfaces 16
2.1 Spectrometer for Two-Electron Spectroscopy of Solid Surfaces 17
2.1.1 Coincidence (e,2e) Scattering from Surfaces in Back Reflection Geometry 18
2.1.2 Principle of Time-of-Flight (TOF) Energy Measurement 20
2.1.3 Magnetic Field Compensation 25
2.1.4 Combination of Time-of-Flight and Coincidence Techniques 27
2.1.5 Data Processing and Various Presentations of Measured (e,2e) Distributions 29
2.1.6 Spin-Polarized Electron Beam 35
2.2 Single-Step Versus Multi-step Electron Scattering in the (e,2e) Reaction on Surfaces 40
2.2.1 Experimental Evidence of the Single-Step Scattering Contribution to the (e,2e) Spectrum 43
2.2.2 Diffraction of Correlated Electron Pairs on a Crystal Surface 46
2.3 Surface Sensitivity of the Low-Energy (e,2e) Scattering in a Back-Reflection Geometry 54
2.3.1 Contribution of Surface States on W(100) to the (e,2e) Spectrum Measured with Low-Energy Primary Electrons 55
2.3.2 Observation of Oxygen Adsorption on W(110) by Low-Energy (e,2e) Spectroscopy 60
2.4 Plasmon-Assisted (e,2e) Scattering from a Surface 67
2.4.1 Secondary Electron Emission from Dielectrics 68
2.4.2 Plasmons in Dielectrics 69
2.4.3 Plasmon-Assisted (e,2e) Scattering on LiF Films 70
2.4.4 Plasmon-Assisted (e,2e) Scattering on Metals 73
2.5 Application of (e,2e) Spectroscopy for Studying Surfaces and Surface Phenomena 76
2.5.1 Measurements of Energy Band Parameters of a Dielectric Surface 76
2.5.2 Two-Electron Distributions from Various Materials Excited by Electron Impact 79
2.6 Mechanism of (e,2e) Reaction in Metals, Semiconductors and Dielectrics 88
2.7 Selection Rules in (e,2e) Scattering from Surfaces 93
2.7.1 First Selection Rule 93
2.7.2 Second Selection Rule 94
References 95
3 Spin-Polarized (e,2e) Spectroscopy of Surfaces 98
3.1 Description of Polarized Electrons and Spin-Dependent Interactions 99
3.1.1 Spin Operator 99
3.1.2 Polarization of an Electron Beam 100
3.1.3 Influence of Electron-Electron Scattering on the Polarization of an Electron Beam 103
3.2 Spin-Orbit Interaction in Electron Scattering 106
3.2.1 Electron Scattering Cross Section in a Relativistic Case (Taking into Account Spin-Orbit Interaction) 110
3.2.2 Spin-Orbit Effects in the (e,2e) Scattering on Surfaces 113
3.3 Role of Electron Exchange in the Electron Scattering (Basics) 118
3.3.1 Electron Exchange in the (e,2e) Scattering on a Ferromagnetic Surface 120
3.3.2 The Probability of Two-Electron Emission from a Ferromagnetic Surface Under Spin-Polarized Electron Impact 123
3.3.3 Connection Between Measured Asymmetry of the (e,2e) Spectrum and Spin-Dependent Electronic Structure of the Target 124
3.4 Experimental Observation of Spin-Orbit Effects in Spin-Polarized (e,2e) Spectroscopy on Surfaces 127
3.4.1 Spin-Orbit Effect in the (e,2e) Scattering from Tungsten Crystal 127
3.4.2 Anisotropy of Spin-Orbit Interaction in W(110) by Spin-Polarized Two-Electron Spectroscopy 131
3.4.3 Spin-Orbit Effects in the (e,2e) Scattering from Au(111) Film on W(110) Surface 136
3.4.4 Comparison of the Spin-Polarized (e,2e) Scattering from W(110) and Au(111) 143
3.4.5 Influence of the Oxygen Adsorption on Spin-Polarized Two-Electron Scattering from W(110) 144
3.5 Experimental Observation of the Exchange Effect in (e,2e) Scattering on Ferromagnetic Surfaces 149
3.5.1 Fe(110) Single Crystal 151
3.5.2 Fe Films Deposited on W(110) Surface 159
3.5.3 Thin Co Films Deposited on W(110) 163
3.6 Application of the Spin-Polarized (e,2e) Spectroscopy for Studying Spin Effects in Multilayered Structures 169
3.6.1 Cobalt Film on W(110) with Ni Buffer Layer 169
3.6.2 Probing Spin-Related Properties of Magnetic/Nonmagnetic Double Layer on W(110) Using Spin-Polarized (e,2e) Spectroscopy 176
3.7 Visualizing an Exchange-Correlation Hole Using Spin-Polarized (e,2e) Scattering 179
3.7.1 Concept of “Exchange-Correlation Hole” 179
3.7.2 Approach to Visualize an Exchange-Correlation Hole 181
3.8 Spin Entanglement of Electron Pairs After (e,2e) Scattering at Surfaces 193
3.8.1 Definition of Entanglement of a Two-Electron System 193
3.8.2 Creation of Entanglement in Electron-Electron Scattering at Surfaces 194
3.8.3 Polarization of a Single Electron and Entanglement of the Pair 199
3.8.4 Experimental Demonstration of Spin Entanglement in (e,2e) Scattering 204
References 208
4 Emission of Correlated Electron Pairs from Surfaces Induced by Photons, Positrons and Ions 213
4.1 Emission of Correlated Electron Pairs from a Solid Surface upon Single Photon Absorption 213
4.2 Positron-Induced Positron-Electron Pairs Emission from Surfaces 221
4.3 Ion-Induced Correlated Electron Pairs Emission from Surfaces 225
References 232
Epilogue 234
Index 236