Semiconductor electrochemistry /
"Providing both an introduction and an up-to-date survey of the entire field, this text captivates the reader with its clear style and inspiring, yet solid presentation. The significantly expanded second edition of this milestone work is supplemented by a completely new chapter on the hot topic...
| Κύριος συγγραφέας: | |
|---|---|
| Μορφή: | Ηλ. βιβλίο |
| Γλώσσα: | English |
| Έκδοση: |
Weinheim :
Wiley-VCH,
2015.
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| Έκδοση: | Second edition. |
| Θέματα: | |
| Διαθέσιμο Online: | Full Text via HEAL-Link |
Πίνακας περιεχομένων:
- Related Titles; Title Page; Copyright Page; Preface to the Second Edition; Preface; Chapter 1: Principles of Semiconductor Physics; 1.1 Crystal Structure; 1.2 Energy Levels in Solids; 1.3 Optical Properties; 1.4 Density of States and Carrier Concentrations; 1.5 Carrier Transport Phenomena; 1.6 Excitation and Recombination of Charge Carriers; 1.7 Fermi Levels under Nonequilibrium Conditions; Chapter 2: Semiconductor Surfaces and Solid-Solid Junctions; 2.1 Metal and Semiconductor Surfaces in a Vacuum; 2.2 Metal-Semiconductor Contacts (Schottky Junctions); 2.3 p-n Junctions.
- 2.4 Ohmic Contacts2.5 Photovoltages and Photocurrents; 2.6 Surface Recombination; Chapter 3: Electrochemical Systems; 3.1 Electrolytes; 3.2 Potentials and Thermodynamics of Electrochemical Cells; Chapter 4: Experimental Techniques; 4.1 Electrode Preparation; 4.2 Current-Voltage Measurements; 4.3 Measurements of Surface Recombination and Minority Carrier Injection; 4.4 Impedance Measurements; 4.5 Surface Conductivity Measurement; 4.6 Flash Photolysis Investigations; 4.7 Surface Science Techniques; Chapter 5: Solid-Liquid Interface; 5.1 Structure of the Interface and Adsorption.
- 5.2 Charge and Potential Distribution at the Interface5.3 Analysis of the Potential Distribution; 5.4 Modification of Semiconductor Surfaces; Chapter 6: Electron Transfer Theories; 6.1 The Theory of Marcus; 6.2 The Gerischer Model; 6.3 Quantum Mechanical Treatments of Electron Transfer Processes; 6.4 The Problem of Deriving Rate Constants; 6.5 Comparison of Theories; Chapter 7: Charge Transfer Processes at the Semiconductor-Liquid Interface; 7.1 Charge Transfer Processes at Metal Electrodes; 7.2 Qualitative Description of Current-Potential Curves at Semiconductor Electrodes.
- 7.3 One-step Redox Reactions7.4 The Quasi-Fermi-Level Concept; 7.5 Determination of the Reorganization Energy; 7.6 Two-step Redox Processes; 7.7 Photoluminescence and Electroluminescence; 7.8 Hot Carrier Processes; 7.9 Catalysis of Electrode Reactions; Chapter 8: Electrochemical Decomposition of Semiconductors; 8.1 Anodic Dissolution Reactions; 8.2 Cathodic Decomposition; 8.3 Dissolution under Open Circuit Conditions; 8.4 Energetics and Thermodynamics of Corrosion; 8.5 Competition between Redox Reaction and Anodic Dissolution; 8.6 Formation of Porous Semiconductor Surfaces.
- Chapter 9: Photoreactions at Semiconductor Particles9.1 Quantum Size Effects; 9.2 Charge Transfer Processes at Semiconductor Particles; 9.3 Charge Transfer Processes at Quantum Well Electrodes (MQW, SQW); 9.4 Photoelectrochemical Reactions at Nanocrystalline Semiconductor Layers; Chapter 10: Electron Transfer Processes between Excited Molecules and Semiconductor Electrodes; 10.1 Energy Levels of Excited Molecules; 10.2 Reactions at Semiconductor Electrodes; 10.2.4Sensitization Processes at Semiconductor Surfaces Modified by Dye Monolayers; 10.3 Comparison with Reactions at Metal Electrodes.
