Designing Next-Generation Devices
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Köp båda 2 för 2640 kr1. Building Three dimensional Nanostructured Devices by Self-Assembly by Steve Hu, Jeong-Hyun Cho and David H. Gracias Summary 1.1.0 The pressing need for three dimensional patterned nanofabrication 1.2.0 Self-assembly using molecular linkages 1.2.1 Three dimensional self-assembly using protein linkages 1.2.2 Three dimensional self-assembly with DNA linkages 1.3.0 Three dimensional self-assembly using physical forces 1.4.0 Three dimensional patterned nanofabrication by curving and bending nanostructures 1.4.1 Curving hingeless nanostructures using stress 1.4.2 Three dimensional nanofabrication by bending hinged panels to create patterned polyhedral nanoparticles 1.5.0 Conclusions Acknowledgements References 2. Bio-inspired Three-Dimensional Nanoarchitectures by Jian Shi and Xudong Wang 2.1 Introduction 2.2 Historical Perspective 2.3 Bio-inspired Nanophotonics 2.3.1 Photonic Crystals 2.3.2 Color Mine in Nature 2.3.3 Natural Photonic Crystals 2.4 Bio-inspired Fabrication of Nanostrctures 2.4.1 Biomineralization 2.4.2 Biological Fine Structure Duplication 2.5 Bio-inspired Functionality 2.6 Conclusion References 3. Building 3D Micro- and Nanostructures through Nanoimprint by Xing Cheng 3.1 Introduction to 3D structure fabrication through nanoimprint 3.2 Overview of nanoimprint lithography 3.2.1 Fundamentals of nanoimprint lithography 3.2.2 Materials for nanoimprint lithography] 3.3 Building 3D Nanostructures by Nanoimprint 3.3.1 Direct patterning of 3D structures in one step 3.3.1.1 Replicating 3D polymer structures from 3D templates 3.3.1.2 Applications of 3D polymer structures by one-step nanoimprint 3.3.2 Building 3D nanostructures by transfer bonding and sequential layer stacking 3.3.2.1 Principles of transfer bonding and sequential layerstacking 3.3.2.2 3D structures built by transfer bonding and sequential layer stacking 3.3.2.3 Defect modes and process yield of transfer bonding and sequential layer stacking 3.3.3 Building 3D nanostructures by two consecutive nanoimprints 3.4 Summary and future outlook References 4. Electrochemical Growth of Nanostructured Materials by Jin-Hee Lim and John B. Wiley 4.1 Magnetic Nanomaterials 4.2 Semiconductor Nanostructures 4.3 Thermoelectric Nanomaterials 4.4 Conducting Polymer Nanostructures 4.5 Nanotube and Core-Shell Nanostructures 4.6 Porous Au Nanowires 4.7 Modification of Nanowires 4.8 Functionalization of Nanowires 4.9 Nanostructure Arrays on Substrates 4.10 Patterning of Nanowires Acknowledgment 5. Three dimensional micro/nanomaterials generated by fiber drawing nanomanufacturing by Zeyu Ma, Yan Hong, Shujiang Ding, Minghui Zhang, Maniul Hossain, Ming Su 5.1 Introduction 5.2 Fiber draw tower 5.3 Materials selections 5.4 Drawing process 5.5 Size design 5.6 3D assembling 5.7 Metallic nanowires 5.8 Semiconductor nanowires 5.9 Glass microchannel array 5.10 Differential etching of glasses 5.11 Glass microspike array 5.12 Hybrid glass membranes 5.13 Textured structure of encapsulated paraffin wax microfiber 5.14 Conclusions References 6.0 One-Dimensional Metal Oxide Nanostructures for Photoelectrochemical Hydrogen Generation by Yat Li 6.1 Introduction 6.1.1 Photoelectrochemical hydrogen generation6.1.2 Challenges in Metal Oxide based PEC hydrogen generation 6.1.3 One-Dimensional Nanomaterials for Photoelectrodes 6.2 Pristine Metal Oxide Nanowire/Nanotube-Arrayed Photoelectrodes 6.2.1 Nanowire arrayed photoelectrodes 6.2.1.1 Hematite (-Fe2O3) 6.2.1.2. Titanium Oxide (TiO2) and Zinc Oxide (ZnO)6.2.1.3. Tungsten Trioxide (WO3) 6.2.2 Nanotube arrayed photoelectrodes 6.3 Element-Doped Metal Oxide 1D Nanostructures 6.3.1 TiO2 nanostructures 6.3.2. ZnO nanostructures 6.3.3 Hematite (-Fe2O3) nanostructures 6.4 Quantum Dot Sensitizations 6.4.1 Background 6.4.2 Quantum Dot Sensitized ZnO Nanowires 6.4.3 Quantum Dot Co-Sensitized Nanowires 6.4.4 Double-sided Quantum Dot Sensitization 6.5 Synergistic Effect of Quantum Dot Sensitization and Elemental Doping 6.6 Concluding Remarks Referenc