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Table of Contents
Preface to Progress in Nanophotonics; Preface to Volume IV; Contents; Contributors; 1 Progress in Dressed Photon Technology and the Future; 1.1 Introduction; 1.2 The Dressed Photon as a Physical Picture of an Off-Shell Photon; 1.3 Applications of Dressed Photons; 1.3.1 Optical Functional Devices; 1.3.2 Nano-fabrication; 1.3.3 Energy Conversion; 1.3.4 Photon Breeding Devices; 1.3.5 Information Processing Systems; 1.3.6 Novel Theoretical Models and Future Outlook; 1.4 Summary; References
3.2 Near-Field Assisted Energy Upconversion3.2.1 Hydrogen Generation; 3.2.2 CO2 Reduction; 3.3 Near-Field Etching; 3.3.1 Flat Surface; 3.3.2 Three Dimensional Structures; 3.3.3 Polarization Dependence; 3.4 Summary; References; 4 Nanophotonics-Based Self-optimization for Macro-optical Applications; 4.1 Introduction; 4.1.1 Self-assembly for Nanometric-Fabrication; 4.1.2 Nanophotonics for Self-assembly; 4.2 Nanophotonic Droplet; 4.2.1 Nanometric Alignment for Optical Energy Transfer; 4.2.2 Size Resonance-Based Nanometric Coupling; 4.2.3 Phonon-assisted Photo-Curing Process
4.2.4 Experimental Demonstrations4.2.5 Dynamics of the Coupling Process; 4.2.6 High-Yield Optical Energy Conversion; 4.2.7 Further Discussions; 4.3 Optical Annealing-Based Electrooptical Device; 4.3.1 General Fabrication of Oxide Semiconductor; 4.3.2 Phonon-Assisted Optical Annealing; 4.3.3 Device Fabrication; 4.3.4 Demonstration as Polarization Rotator; 4.3.5 Demonstration as Optical Switching; 4.4 Summary; References; 5 Ultraflexible Organic Electronics and Photonics; 5.1 Introduction; 5.2 Background and Purpose of Research; 5.3 Ultrathin Organic LEDs
3.2 Near-Field Assisted Energy Upconversion3.2.1 Hydrogen Generation; 3.2.2 CO2 Reduction; 3.3 Near-Field Etching; 3.3.1 Flat Surface; 3.3.2 Three Dimensional Structures; 3.3.3 Polarization Dependence; 3.4 Summary; References; 4 Nanophotonics-Based Self-optimization for Macro-optical Applications; 4.1 Introduction; 4.1.1 Self-assembly for Nanometric-Fabrication; 4.1.2 Nanophotonics for Self-assembly; 4.2 Nanophotonic Droplet; 4.2.1 Nanometric Alignment for Optical Energy Transfer; 4.2.2 Size Resonance-Based Nanometric Coupling; 4.2.3 Phonon-assisted Photo-Curing Process
4.2.4 Experimental Demonstrations4.2.5 Dynamics of the Coupling Process; 4.2.6 High-Yield Optical Energy Conversion; 4.2.7 Further Discussions; 4.3 Optical Annealing-Based Electrooptical Device; 4.3.1 General Fabrication of Oxide Semiconductor; 4.3.2 Phonon-Assisted Optical Annealing; 4.3.3 Device Fabrication; 4.3.4 Demonstration as Polarization Rotator; 4.3.5 Demonstration as Optical Switching; 4.4 Summary; References; 5 Ultraflexible Organic Electronics and Photonics; 5.1 Introduction; 5.2 Background and Purpose of Research; 5.3 Ultrathin Organic LEDs