05926cam a2200685Ii 4500 ocn889949229 OCoLC 20171026112114.0 m o d cr cnu---unuuu 140904s2014 enka ob 000 0 eng d 9781118984277 (electronic bk.) 1118984277 (electronic bk.) 9781118984291 (electronic bk.) 1118984293 (electronic bk.) 1848216874 9781848216877 9781848216877 CHBIS 010259752 CHVBK 325941653 DEBSZ 431746052 GBVCP 81486693X NZ1 15908974 DEBBG BV043397097 (OCoLC)889949229 (OCoLC)887507338 (OCoLC)961660923 (OCoLC)962720855 DG1 eng rda pn DG1 N$T YDXCP OHI EBLCP IDEBK CDX E7B VRC RECBK DEBSZ COO OCLCQ DEBBG MAIN TK7874.85 .W53 2014 TEC 009070 bisacsh 621.381045 23 Wide band gap semiconductor nanowires, 2 : Heterostructures and optoelectronic devices / edited by Vincent Consonni, Guy Feuillet. [electronic resource] Heterostructures and optoelectronic devices London, UK : ISTE, 2014. 1 online resource : illustrations (black and white). text txt rdacontent computer c rdamedia online resource cr rdacarrier Electronics engineering series Includes bibliographical references. Cover; Title Page; Copyright; Contents; Preface; Part 1: GaN and ZnO Nanowire Heterostructures; Chapter 1: AlGaN/GaN Nanowire Heterostructures ; 1.1. A model system for AlGaN/GaN heterostructures; 1.2. Axial AlGaN/GaN nanowire heterostructures; 1.2.1. Structural properties of axial AlGaN/GaN nanowire heterostructures; 1.2.2. Optical properties of axial AlGaN/GaN nanowire heterostructures; 1.2.3. Lateral internal electric fields; 1.2.4. Axial internal electric fields; 1.2.5. Optical characterization of single-AlGaN/GaN nanowires containing GaN nanodisks; 1.2.6. Electrical transport properties. 1.3. AlGaN/GaN core-shell nanowire heterostructures1.3.1. Structural properties; 1.3.2. Optical characteristics; 1.3.3. Electronic properties; 1.3.4. True one-dimensional GaN quantum wire (QWR) second-order self-assembly; 1.4. Application examples; 1.4.1. AlGaN/GaN NWH optochemical gas sensors; 1.4.2. AlGaN/GaN nanowire heterostructure resonant tunneling diodes; 1.5. Conclusions; 1.6. Bibliography; Chapter 2: InGaN Nanowire Heterostructures; 2.1. Introduction; 2.2. Self-assembled InGaN nanowires; 2.3. X-ray characterization of InGaN nanowires. 2.4. InGaN nanodisks and nanoislands in GaN nanowires2.5. Selective area growth (SAG) of InGaN nanowires; 2.6. Conclusion; 2.7. Bibliography; Chapter 3: ZnO-Based Nanowire Heterostructures; 3.1. Introduction; 3.2. Designing ZnO-based nanowire heterostructures; 3.3. Growth of ZnxMg1-xO/ZnO core-shell heterostructures by MOVPE; 3.4. Misfit relaxation processes in ZnxMg1-xO/ZnO core-shell structures; 3.5. Optical efficiency of core-shell oxide-based nanowire heterostructures; 3.6. Axial nanowire heterostructures; 3.7. Conclusions and perspectives; 3.8. Bibliography. Chapter 4: ZnO and GaN Nanowire-based Type II Heterostructures4.1. Semiconductor heterostructures; 4.2. Type II heterostructures; 4.3. Optimal device architecture; 4.4. Electronic structure of type II core-shell nanowires; 4.5. Synthesis of the type II core-shell nanowires and their signatures; 4.6. Demonstration of type II effects in ZnO-ZnSe core-shell nanowires and photovoltaic devices; 4.7. Summary; 4.8. Acknowledgments; 4.9. Bibliography; Part 2: Integration of GaN and ZnO Nanowires in Optoelectronic Devices; Chapter 5: Axial GaN Nanowire-based LEDs; 5.1. Introduction. 5.2. Top-down GaN-based axial nanowire LEDs5.2.1. Fabrication of top-down GaN-based axial nanowires; 5.2.2. Device fabrication of axial nanowire LEDs; 5.2.3. Performance characteristics of top-down axial nanowire LEDs; 5.3. Bottom-up GaN-based axial nanowire LEDs; 5.3.1. Growth techniques; 5.3.2. Doping, polarity and surface charge properties; 5.3.3. Design and typical performance of bottom-up axial nanowire LEDs; 5.3.3.1. Disk/well-in-a-wire LEDs; 5.3.3.2. Double heterostructure nanowire LEDs; 5.3.3.3. Dot-in-a-wire nanowire LEDs; 5.3.3.4. Polarization-induced p-n junction nanowire LEDs. This book, the second of two volumes, describes heterostructures and optoelectronic devices made from GaN and ZnO nanowires. Over the last decade, the number of publications on GaN and ZnO nanowires has grown exponentially, in particular for their potential optical applications in LEDs, lasers, UV detectors or solar cells. So far, such applications are still in their infancy, which we analyze as being mostly due to a lack of understanding and control of the growth of nanowires and related heterostructures. Furthermore, dealing with two different but related semiconductors such as ZnO and. Print version record. Optoelectronic devices. Nanowires. TECHNOLOGY & ENGINEERING Mechanical. bisacsh Nanowires. fast (OCoLC)fst01032641 Optoelectronic devices. fast (OCoLC)fst01046908 Electronic books. Electronic books. Consonni, Vincent, editor. Feuillet, Guy, editor. Print version: Wide band gap semiconductor nanowires 9781848215979 (OCoLC)870426617 Electronics engineering series (London, England) http://onlinelibrary.wiley.com/book/10.1002/9781118984291 Wiley Online Library ddc BK 207651 207651