Quantum Theory of Transport Properties of Single Molecules
Pan Stanford Publishing Pte Ltd (Verlag)
978-981-4267-31-1 (ISBN)
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The quantum transport theory, which dates back to the time of the Landauer theory in the field of mesoscopic physics, is now expanding its power on materials science and chemistry by earning chemical accuracy and physical reality and has become a new subject of non-equilibrium quantum transport theory for charge and heat at nanoscale. This growing subject invites cross-disciplinary developments, for example, the local heating theory developed earlier was examined and applied to the self-heating problem in the field of semiconductor- and nanoelectronic-device physics. This book compiles 25 key published papers to provide readers with convenient and comprehensive access to the important results and developments in the field. The book will appeal to a wide range of readers from varied backgrounds, especially those involved in charge- and/or heat-transport problems that widely spread over various subjects in materials science, chemistry, electric engineering, and condensed matter physics.
Yoshihiro Asai is a former director of a research center at the National Institute of Advanced Industrial Science and Technology (AIST), Japan. He joined Prof. Ken-ichi Fukui’s group at Kyoto University, Japan, and was awarded a PhD in 1987 in the field of quantum chemistry. He then moved as a tenured researcher to Dr. J. Kondo’s group at Electrotechnical Laboratory (ETL) and started research on condensed matter physics theory, including strongly correlated electron systems, superconductivity, computational physics, and non-equilibrium transport. His research has been focused on inelastic electric currents, electron and phonon currents, local heating, and vibronic effects on current noise. Dr. Asai’s work contributes to the understanding of fundamental physical processes and has practical implications for technologies such as nanoelectronics, thermoelectric devices, and quantum materials. Marius E. Bürkle joined Yoshihiro Asai’s group as a JSPS fellow and became a chief senior researcher at AIST. He joined Prof. Gerd Schön’s group at Karlsruhe Institute of Technology and was awarded a PhD in 2011 for his thesis on “Ab initio description of electron transport through nanoscale systems.” His research is focused on nanoscale systems, particularly electron transport, as well as single-molecule charge transport and quantum interference. His work includes studies on heat dissipation and its relation to thermopower in single-molecule junctions, nanoscale orchestration, thermoelectric properties, and quantum transport.
1. Theory of Length-Dependent Conductance in One-Dimensional Chains
2. Long-Range Electron Transport of Ruthenium-Centered Multilayer Films via a Stepping-Stone Mechanism
3. The Orbital Selection Rule for Molecular Conductance as Manifested in Tetraphenyl-Based Molecular Junctions
4. Gate Controlling of Quantum Interference and Direct Observation of Anti-resonances in Single Molecule Charge Transport
5. Switch of Conducting Orbital by Bias-Induced Electronic Contact Asymmetry in a Bipyrimidinyl-biphenyl Diblock Molecule: Mechanism to Achieve a pn Directional Molecular Diode
6. Controlling Formation of Single-Molecule Junctions by Electrochemical Reduction of Diazonium Terminal Groups
7. Toward Multiple Conductance Pathways with Heterocycle-Based Oligo(phenyleneethynylene) Derivatives
8. Theory of Inelastic Electric Current through Single Molecules
9. Theoretical Study of the Lineshape of Inelastic Electron Tunneling Spectroscopy
10. Inelastic Transport and Low-Bias Rectification in a Single-Molecule Diode
11. Nonequilibrium Phonon Effects on Transport Properties through Atomic and Molecular Bridge Junctions
12. Theory of Local Heating in Single Molecular Bridge Junctions
13. Vibronic Spectroscopy Using Current Noise
14. Universal Temperature Crossover Behavior of Electrical Conductance in a Single Oligothiophene Molecular Wire
15. Theory of Electric Conductance of DNA Molecule
16. First-Principles Calculation of the Thermoelectric Figure of Merit for [2,2]Paracyclophane-Based Single-Molecule Junctions
17. Thermal Conductance of Teflon and Polyethylene: Insight from an Atomistic, Single-Molecule Level
18. How to Probe the Limits of the Wiedemann–Franz Law at Nanoscale
19. Thermoelectricity at the Molecular Scale: A Large Seebeck Effect in Endohedral Metallofullerenes
20. Thermoelectric Efficiency of Organometallic Complex Wires via Quantum Resonance Effect and Long-Range Electric Transport Property
21. Heat Dissipation and Its Relation to Thermopower in Single-Molecule Junctions
22. Thermoelectric Effect and Its Dependence on Molecular Length and Sequence in Single DNA Molecules
23. The Effect of a Ta Oxygen Scavenger Layer on HfO2-Based Resistive Switching Behavior: Thermodynamic Stability, Electronic Structure, and Low-Bias Transport
24. Competitive Effects of Oxygen Vacancy Formation and Interfacial Oxidation on an Ultra-Thin HfO2-Based Resistive Switching Memory: Beyond Filament and Charge Hopping Models
25. Resistive Switching Mechanism of GeTe–Sb2Te3 Interfacial Phase Change Memory and Topological Properties of Embedded Two-Dimensional States
Erscheinungsdatum | 16.01.2021 |
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Zusatzinfo | 19 Tables, black and white; 60 Line drawings, color; 95 Line drawings, black and white; 60 Illustrations, color; 95 Illustrations, black and white |
Verlagsort | Singapore |
Sprache | englisch |
Maße | 152 x 229 mm |
Gewicht | 1250 g |
Themenwelt | Naturwissenschaften ► Biologie |
Naturwissenschaften ► Chemie ► Physikalische Chemie | |
Naturwissenschaften ► Physik / Astronomie | |
Technik ► Maschinenbau | |
Technik ► Umwelttechnik / Biotechnologie | |
ISBN-10 | 981-4267-31-7 / 9814267317 |
ISBN-13 | 978-981-4267-31-1 / 9789814267311 |
Zustand | Neuware |
Informationen gemäß Produktsicherheitsverordnung (GPSR) | |
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