Chichester, West Sussex, : Wiley, 2011

1-283-40526-1

9786613405265

1-119-99104-8

1-119-99103-X

1 online resource (387 p.)

Wiley series in materials for electronic and optoelectronic applications

TEC021000

LittonCole W

ReynoldsDonald C

CollinsThomas C. <1936->

669/.52

Zinc oxide

Electronic apparatus and appliances - Materials

Optoelectronic devices - Materials

Electronic books.

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Zinc Oxide Materials for Electronic and Optoelectronic Device Applications; Contents; Series Preface; Preface; List of Contributors; 1 Fundamental Properties of ZnO; 1.1 Introduction; 1.1.1 Overview; 1.1.2 Organization of Chapter; 1.2 Band Structure; 1.2.1 Valence and Conduction Bands; 1.3 Optical Properties; 1.3.1 Free and Bound Excitons; 1.3.2 Effects of External Magnetic Field on ZnO Excitons; 1.3.3 Strain Field; 1.3.4 Spatial Resonance Dispersion; 1.4 Electrical Properties; 1.4.1 Intrinsic Electronic Transport Properties; 1.4.2 n-type Doping and Donor Levels

1.4.3 p-type Doping and Dopability1.4.4 Schottky Barriers and Ohmic Contacts; 1.5 Band Gap Engineering; 1.5.1 Homovalent Heterostructures; 1.5.2 Heterovalent Heterostructures; 1.6 Spintronics; 1.7 Summary; References; 2 Optical Properties of ZnO; 2.1 Introduction; 2.2 Free Excitons; 2.3 Strain Splitting of the Γ5 and Γ6 Free Excitons in

ZnO; 2.4 Photoluminescence from the Two Polar Faces of ZnO; 2.5 Bound-Exciton Complexes in ZnO; 2.6 Similarities in the Photoluminescence Mechanisms of ZnO and GaN

2.7 The Combined Effects of Screening and Band Gap Renormalization on the Energy of Optical Transitions in ZnO and GaN2.8 Closely Spaced Donor-Acceptor Pairs in ZnO; 2.9 Summary; References; 3 Electrical Transport Properties in Zinc Oxide; 3.1 Introduction; 3.2 Hall-Effect Analysis; 3.2.1 Single-Band Conduction; 3.2.2 Two-Band Mixed Conduction; 3.2.3 Conducting Surface Layers; 3.3 Donor States and n-type Doping; 3.3.1 Native Point Defects - Donors; 3.3.2 Substitutional Donors; 3.4 Hydrogen; 3.5 Acceptor States and p-type Doping; 3.5.1 Native Point Defects - Acceptors

3.5.2 Substitutional Acceptors3.6 Photoconductivity; 3.7 Summary; References; 4 ZnO Surface Properties and Schottky Contacts; 4.1 Historical Background of Schottky Contacts on ZnO; 4.1.1 ZnO Surface Effects; 4.1.2 Early Schottky Barrier Studies; 4.2 Recent Schottky Barrier Studies; 4.2.1 Surface Cleaning in Vacuum; 4.2.2 Surface Cleaning Effects on Impurities and Defects; 4.3 The Influence of Surface Preparation on Schottky Barriers; 4.4 The Influence of Defects on Schottky Barriers; 4.5 The Influence of ZnO Polarity on Schottky Barriers; 4.6 The Influence of Chemistry

4.7 Charge Transport and Extended Metal-ZnO Schottky Barriers4.8 Conclusion; Acknowledgements; References; 5 Native Point Defects and Doping in ZnO; 5.1 Introduction; 5.2 Theoretical Framework; 5.3 Native Point Defects; 5.3.1 Oxygen Vacancies; 5.3.2 Zinc Interstitials; 5.3.3 Zinc Antisites; 5.3.4 Zinc Vacancies; 5.3.5 Defect Migration; 5.4 Donor Impurities; 5.4.1 Aluminum, Gallium and Indium; 5.4.2 Fluorine; 5.4.3 Hydrogen; 5.5 Acceptor Impurities; 5.5.1 Lithium; 5.5.2 Copper; 5.5.3 Nitrogen; 5.5.4 Phosphorous, Arsenic and Antimony; 5.5.5 Co-Doping; 5.6 Isoelectronic Impurities

Acknowledgements

Zinc Oxide (ZnO) powder has been widely used as a white paint pigment and industrial processing chemical for nearly 150 years. However, following a rediscovery of ZnO and its potential applications in the 1950s, science and industry alike began to realize that ZnO had many interesting novel properties that were worthy of further investigation. ZnO is a leading candidate for the next generation of electronics, and its biocompatibility makes it viable for medical devices. This book covers recent advances including crystal growth, processing and doping and also discusses the problems and issues