Green Photonics and Smart Photonics.

Cover -- Half Title -- Series -- Title -- Copyright -- Contents -- Preface -- List of Contributors -- List of Figures -- List of Tables -- List of Abbreviations -- Introduction -- 1 Thermal Field Study of Multichip LED Module -- 1.1 Introduction -- 1.1.1 Background of LED -- 1.1.2 Literatures -- 1.2 Structure and Properties of LED Package -- 1.3 Theoretical Studies -- 1.3.1 Heat Transfer -- 1.3.2 Thermal Resistance -- 1.4 Simulation -- 1.5 General Results on Thermal Field Analysis -- 1.5.1 In Terms of K Factor -- 1.5.2 In Terms of Cooling Curve -- 1.5.3 In Terms of Structure Functions -- 1.5.4 In Terms of Estimated Junction Temperature -- References -- 2 Modeling and Simulation of Ge/Si-Nanodisk Array for QD-based IB Solar Cells -- 2.1 Introduction -- 2.2 Fabrication of GE/Si-Nanodisk -- 2.3 The Computational Model -- 2.3.1 Calculation of Electronic Band Structures -- 2.3.2 Calculation of DoSs -- 2.3.3 IBSC Model -- 2.4 1D Superlattice -- 2.5 In-Plane Ge/Si QDs Superlattice -- 2.5.1 Electronic Band Structure -- 2.5.2 Density of States -- 2.5.3 QDs IB SC -- 2.6 Conclusions -- References -- 3 Sputtering Epitaxy of Si and Ge for Application to Solar Cells -- 3.1 Introduction -- 3.2 SE of Si and Ge -- 3.3 Characteristics of Si and Ge Films -- 3.4 Conductivity Control of Epitaxial Ge and Si Films -- 3.5 SC Characteristics -- 3.6 Conclusion -- References -- 4 Non-Stoichiometric SiC-based Solar Cells -- 4.1 Introduction -- 4.2 All Non-Stoichiometric SixC1−x-based p-n Junction SCs -- 4.2.1 The Synthesis of the Non-Stoichiometric SixC1−x-based p-n Junction SC -- 4.2.2 The XPS Analysis of Non-Stoichiometric SixC1−x Film -- 4.2.3 The Optical Absorption Analysis of the Non-Stoichiometric SixC1−x Film -- 4.2.4 The PC Simulation of the Non-Stoichiometric SixC1−x-based p-n Junction SC.

4.2.5 The Performance of the Non-Stoichiometric SixC1−x-based p-n Junction SC -- 4.3 All Non-Stoichiometric SixC1−x-based p-i-n Junction SC -- 4.3.1 The Synthesis of the Non-Stoichiometric SixC1−x-based p-i-n Junction SC -- 4.3.2 Optimizing the Resistivity of n-Type and p-Type Non-Stoichiometric SixC1−x Films by Detuning the PH3- and B2H6-Doping Fluence Ratio in Reactant Gas Recipe -- 4.3.3 The Performance of the Non-Stoichiometric SixC1−x-based p-i-n Junction SC -- 4.4 All Non-Stoichiometric SixC1−x-based p-i-n Junction SCs with Lower C/Si Composition Ratio Grown Intrinsic SixC1−x Layer -- 4.4.1 The Fabrication of the Non-Stoichiometric SixC1−x-based p-i-n Junction SC -- 4.4.2 The XPS Analysis on the Composition of the N on-Stoichiometric SixC1−x Films -- 4.4.3 The Optical Absorption Analysis and PC Simulation of the Non-Stoichiometric SixC1−x Films -- 4.4.4 The Performance of Non-Stoichiometric SixC1−x-based SCs -- 4.5 Conclusion -- References -- 5 Water Splitting Using GaN-based Working Electrodes for Hydrogen Generation with Bias by Solar Cells -- 5.1 Introduction -- 5.2 Experiments -- 5.3 Results and Discussions -- 5.4 Conclusion -- References -- 6 Fiber Amplifiers for Photonic Communication and Sensing -- 6.1 Introduction -- 6.2 Experimental Setup -- 6.2.1 Bidirectional EDFA -- 6.2.2 Raman Fiber Amplifier -- 6.2.3 Bidirectional Hybrid Fiber Amplifier -- 6.2.4 High-Power Erbium Ytterbium Co-Doped Fiber Amplifier (EYDFA) -- 6.3 Results and Discussion -- 6.3.1 Bidirectional EDFA -- 6.3.2 Raman Fiber Amplifier -- 6.3.3 Bidirectional Hybrid Fiber Amplifier -- 6.3.4 High-Power EYDF Amplifier -- 6.4 Conclusion -- References -- 7 High-Sensitivity Pressure, DP, and Random Rotational Angle Fiber Sensors -- 7.1 Fiber Grating Characterization and Fabrication -- 7.2 The Lateral Pressure Sensors based on Fiber Gratings -- 7.2.1 Basic Operation Principle.

7.2.2 Experimental Results -- 7.3 The DP Sensors based on Fiber Gratings -- 7.3.1 Basic Principle -- 7.3.2 Experimental Results -- 7.4 The Rotational Angle Sensors based on Fiber Gratings -- 7.4.1 Basic Operating Principle -- 7.4.2 Experimental Results -- 7.5 Conclusion -- References -- 8 Heterogeneous Integration of Group IV Semiconductors on Si by RMG Method for Implementing High-Speed Optoelectronic Devices -- 8.1 Introduction -- 8.2 Germanium MSM Photodetectors -- 8.3 Self-Assembled Microbonded Ge/Si Heterogeneous Structure -- 8.3.1 Self-Assembled Microbonded Ge on Si by Surface Tension -- 8.3.2 Device Schematics and Fabrication -- 8.3.3 Results and Discussion -- 8.4 Self-Aligned Butt-Coupling of Ge and Si Waveguide -- 8.4.1 Device Schematics and Fabrication -- 8.4.2 Optical Simulation on Coupling Efficiency -- 8.4.3 Measurement Result and Discussion -- 8.5 Germanium-Tin (GeSn) Photodetectors -- 8.5.1 Device Schematics and Fabrication -- 8.5.2 Experimental Results -- 8.6 Conclusion -- References -- 9 SiC Smart Photonic Waveguide Device for Data Processing -- 9.1 Introduction -- 9.1.1 Historical Review of SiC-based Optoelectronic Devices -- 9.1.2 Historical Review of Si-based All-Optical Switching with the Advantages of SiC-based Non-Linear Waveguide Applications -- 9.1.3 Motivation and Chapter Content -- 9.2 Structural Properties of Amorphous Si-Rich SiC -- 9.2.1 Composition of Amorphous Si-Rich SiC -- 9.2.2 Optical Non-Linearity of Amorphous Si-Rich SiC -- 9.3 All Optical Switching in Si-QD-Doped in a-SiC Micro-Ring Resonator -- 9.3.1 Fabrication of Si-QD-Doped in a-SiC Micro-Ring Resonator -- 9.3.2 Operation of SiC Ring Resonator -- 9.4 Conclusion -- References -- 10 Application of Ion Beam Technology in the Synthesis of ZnO Nanostructures -- 10.1 Introduction -- 10.2 Capillaritron Ion Source -- 10.3 ZnO Nanostructures.

10.4 Synthesis of ZnO Nanostructures Utilizing Ion Beam Processing -- 10.5 Experiment and Results -- 10.5.1 Ion Beam Synthesis of Zn Nanoneedles -- 10.5.2 ZnO QDs on Ion Beam Textured Si Substrates -- 10.5.3 ZnO Nanowire by Thermal Oxidation of Metallic Zinc -- 10.5.3.1 Zn foil with ion implantation -- 10.5.3.2 Zn films deposited by ion beam sputter deposition -- 10.5.3.3 Zn films deposited by RF magnetron sputtering -- 10.5.3.4 Zn films deposited by thermal evaporation -- 10.6 Conclusions -- References -- Index -- About the Editors.

This book presents recent advances, both theoretical and applications, reflecting the cutting-edge technologies and research achievements within these research fields.Green Photonics intend to develop photonics technologies that can conserve energy, reduce pollution and create renewable energy.

Description based on publisher supplied metadata and other sources.

Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.