Wide band gap semiconductor nanowires. 2, Heterostructures and optoelectronic devices / edited by Vincent Consonni, Guy Feuillet

Additional Titles: Heterostructures and optoelectronic devices
Published: London, UK : ISTE, 2014.
Physical Description: 1 online resource : illustrations (black and white)
Additional Creators: Consonni, Vincent and Feuillet, Guy

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John Wiley: ezaccess.libraries.psu.edu

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Electronics engineering series (London, England)

Contents

Machine generated contents note: pt. 1 GaN and ZnO Nanowire Heterostructures -- ch. 1 AlGaN/GaN Nanowire Heterostructures / Martin Eickhoff -- 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 heterostructures -- 1.3.1.Structural properties -- 1.3.2.Optical characteristics -- 1.3.3.Electronic properties -- 1.3.4.True one-dimensional GaN quantum wire second-order self-assembly -- 1.4.Application examples -- 1.4.1.AlGaN/GaN nanowire heterostructure optochemical gas sensors -- 1.4.2.AlGaN/GaN nanowire heterostructure resonant tunneling diodes -- 1.5.Conclusions -- 1.6.Bibliography -- ch. 2 InGaN Nanowire Heterostructures / Bruno Daudin -- 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 nanowires -- 2.5.Selective area growth (SAG) of InGaN nanowires -- 2.6.Conclusion -- 2.7.Bibliography -- ch. 3 ZnO-based Nanowire Heterostructures / Pierre Ferret -- 3.1.Introduction -- 3.2.Designing ZnO-based nanowire heterostructures -- 3.3.Growth of ZnxMg1-xO/ZnO core-shell heterostructures by metal-organic vapor phase epitaxy -- 3.4.Misfit relaxation processes in Znx Mg1-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 -- ch. 4 ZnO and GaN Nanowire-based Type II Heterostructures / Yong Zhang -- 4.1.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 -- pt. 2 Integration of GaN and ZnO Nanowires in Optoelectronic Devices -- ch. 5 Axial GaN Nanowire-based LEDs / Zetian Mi -- 5.1.Introduction -- 5.2.Top-down GaN-based axial nanowire LEDs -- 5.2.1.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 -- 5.4.Carrier loss processes of axial nanowire LEDs -- 5.4.1.Auger recombination -- 5.4.2.Electron overflow -- 5.4.3.Surface recombination -- 5.5.Controlling carrier loss of GaN-based nanowire LEDs -- 5.5.1.p-type modulation doping and AlGaN electron blocking layer -- 5.5.2.InGaN/GaN/AlGaN core-shell dot-in-a-wire phosphor-free white LEDs -- 5.6.Conclusions -- 5.7.Bibliography -- ch. 6 Radial GaN Nanowire-based LEDs / Shunfeng Li -- 6.1.Radial GaN nanowire-based LED: an emerging device -- 6.2.Growth of GaN nanowires and radial nanowire-based devices -- 6.3.Radial GaN nanowire-based LED structure -- 6.4.Characteristics of radial NW devices -- 6.5.Further work and perspectives -- 6.6.Bibliography -- ch. 7 GaN Nanowire-based Lasers / Silvija Gradecak -- 7.1.Introduction to nanowire lasers -- 7.2.Theoretical considerations and simulations -- 7.3.The first experimental observations of lasing in nanowires -- 7.4.GaN nanowire-based lasers -- 7.5.Toward wavelength tunability: nanowire lasers based on GaN/InxGa1-xN heterostructures -- 7.6.GaN nanowire lasers coupled with hybrid structures -- 7.7.Challenges and opportunities -- 7.8.Bibliography -- ch. 8 GaN Nanowire-based Ultraviolet Photodetectors / Maria Tchernycheva -- 8.1.Introduction -- 8.2.Growth and fabrication techniques -- 8.3.GaN nanowire photoconductive detectors -- 8.4.p-i-n junction-based GaN nanowire detectors -- 8.5.Single-wire GaN/AIN multiple quantum disk photodetectors -- 8.6.Single-wire InGaN/GaN core-shell photodetectors -- 8.7.Conclusions -- 8.8.Acknowledgments -- 8.9.Bibliography -- ch. 9 ZnO Nanowire-based LEDs / Omer Nour -- 9.1.Outline -- 9.2.Introduction -- 9.3.Growth of ZnO nanowires -- 9.4.White light emission from ZnO nanowires -- 9.5.ZnO NW white LEDs on solid crystalline substrates -- 9.7.ZnO NWs white LEDs on flexible substrates -- 9.7.Enhancing the emission of ZnO nanowire-based LEDs -- 9.8.Conclusion and future prospective -- 9.9.Bibliography -- ch. 10 ZnO Nanowire-based Solar Cells / Jason B. Baxter -- 10.1.Introduction -- 10.1.1.Solar energy conversion and nanostructured solar cells -- 10.1.2.Use of ZnO in solar cells -- 10.2.ZnO nanowire dye-sensitized solar cells -- 10.3.Quantum dot-sensitized nanowire solar cells -- 10.4.Extremely thin absorber solar cells -- 10.5.Nanowire arrays completely filled with inorganic absorbers -- 10.6.ZnO nanorod -- organic hybrid solar cells -- 10.7.ZnO nanowire arrays for photoelectrochemical water splitting -- 10.8.Conclusions -- 10.9.Acknowledgments -- 10.10.Bibliography.

Subject(s)

ISBN

9781118984291 (electronic bk.)
1118984293 (electronic bk.)
9781848216877

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AVAILABLE ONLINE TO AUTHORIZED PSU USERS.

Bibliography Note

Includes bibliographical references.

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