Nanophotonics and Nanofabrication

Starting out with a review of the principles of nanophotonics, this book covers a wide range of novel nanofabrication technologies. The internationally recognized editor pioneered this field of research and here he has gathered together a team of authors to highlight the technical details and procedures for both discrete particle as well as surface structure generation. They also illustrate the application potential of different materials, including biological, inorganic and artificial ones.
An invaluable monograph for materials scientists, chemists, physicists, telecommunications engineers, surface and physical chemists.
From the Contents:Principles and Practice of NanofabricationsNanofabrication by Self–Organization and Other Related TechnologiesFabrications of Quantum Dots and ZnO Nanorods for Nanophotonic DevicesLithography by NanophotonicsNanopatterned Media for High density Storage.Nanophotonics Recording Device for High–Density StorageX–Ray Devices and the Possibility of Applying NanophotonicsFormation of Nanopatterns by Laser AblationQuantum Dot Nanophotonic WaveguidesHierarchy in Optical Near–Fields and its Application to Nanofabrication.

Spis treści:
Preface.
List of Contributors.
1 Introduction. (Motoichi Ohtsu).
1.1 History.
1.2 Fiber Probes and Sensing Systems.
1.3 Theory.
1.4 Devices.
1.5 Fabrications.
1.6 Applications to Systems and Evolution to Related Sciences.
1.7 Toward the Future.
References.
2 Nanofabrication Principles and Practice (Tadashi Kawazoe and Motoichi Ohtsu).
2.1 Adiabatic Nanofabrication.
2.2 Nonadiabatic Nanofabrication.
2.2.1 Nonadiabatic Near–Field Optical Chemical Vapor Deposition.
2.2.2 Nonadiabatic Near–Field Photolithography.
References.
3 Nanofabrications by Self–Organization and Other Related Technologies< /b> (Takashi Yatsui, Wataru Nomura, Kazuya Hirata, Yoshinori Tabata, and Motoichi Ohtsu).
3.1 Introduction.
3.2 Near–Field Optical Chemical Vapor Deposition.
3.3 Self–Assembling Method Via Optical Near–Field Interactions.
3.3.1 Regulating the Size and Position of Nanoparticles Using Size–Dependent Resonance
3.3.2 Self–Assembly of Nanoparticles Using Near–Field Desorption.
3.3.3 One–Dimensional Alignment of Nanoparticles Using an Optical Near–field.
3.4 Near–Field Imprint Lithography.
3.5 Nonadiabatic Optical Near–Field Etching.
References.
4 Fabrication of Quantum Dots for Nanophotonic Devices (Kouichi Akahane and Naokatsu Yamamoto).
4.1 Introduction.
4.2 Fabrication of Self–Assembled QDs.
4.2.1 Control of Density and Emission Wavelength of Self–Assembled QDs
4.2.2 Shortening Emission Wavelengths of Self–Assembled QDs.
4.2.3 Controlling the Density of Self–Assembled QDs.
4.2.4 Fabrication of Self–Assembled QDs with Antimonide–Related Materials.
4.2.5 Fabrication of Ultrahigh–Density QDs.
4.2.6 Summary.
4.3 Fabrication Techniques of Site–Controlled Nanostructures.
4.3.1 Nanopositioning Technique for Quantum Structures with Dioxide Mask.
4.3.2 Artificially Prepared Nanoholes for Arrayed QD Structure Fabrication.
4.3.3 Nanojet Probe Method for Site–Controlled InAs QD Structure.
4.3.4 Scanning Tunneling Probe Assisted Nanolithography for Site–Controlled Individual InAs QD Structure.
4.3.5 Metal–Mask MBE Technique for Selective–Area QD Growth.
4.4 Silicon–Related Quantum Structure Fabrication Technology.
4.4.1 III–V Compound Semiconductor QD on a Si Substrate.
4.4.2 Fabrication Technique of Silicon Nanoparticles as Si–QD Structures.
References.
5 ZnO Nanorod Heterostructures for Nanophotonic Device Applications (Gyu–Chul Yi).
5.1 Introduction.
5.2 ZnO Axial Nanorod Quantum Structures.
5.3 ZnO Radial Nanorod Heterostructures.
5.4 Conclusions.
References.
6 Lithography by Nanophotonics (Ryo Kuroda, Yasuhisa Inao, Shinji Nakazato, Toshiki Ito, Takako Yamaguchi, Tomohiro Yamada, Akira Terao, and Natsuhiko Mizutani).
6.1 Introduction.
6.2 Principle of the Optical Near–Field Lithography.
6.3 Optical Near–Field Lithography System.
6.4 Fabricated Patterns by Optical Near–Field Lithography.
6.5 Improvement of Resolution and Fabricated Ultrafine Patterns.
6.6 Summary.
References.
7 Nanopatterned Media for High–Density Storage (Hiroyuki Hieda).
7.1 Introduction.
7.2 Nanopatterned Media.
7.2.1 Fabrication Process of Nanopatterned Media.
7.3 Block–Copolymer Lithography for Nanopatterned Media.
7.3.1 Self–Assembled Phase Separation of Block–Copolymers.
7.3.2 Fabrication of Magnetic Nanodots by Block–Copolymer Lithography.
7.4 Control of Orientation of Self–Assembled Periodic Patterns of Block–Copolymers.
7.5 Summary.
References.
8 Nanophotonics Recording Device for High–Density Storage (Tetsuya Nishida, Takuya Matsumoto, and Fumiko Akagi).
8.1 Introduction.
8.2 Thermally Assisted Magnetic Recording Simulation.
8.3 The ′Nanobeak′, a Near–Field Optical Probe.
8.4 Bit–Patterned Medium with Magnetic Nanodots.
8.5 Hybrid Recording Experiment.
8.6 Near–Field Optical Efficiency in Hybrid Recording.
8.7 Summary.
References.
9 X–ray Devices and the Possibility of Applying Nanophotonics (Masato Koike, Shinji Miyauchi, Kazuo Sano, and Takashi Imazono).
9.1 Introduction.
9.2 Design of the Multilayer Laminar–Type Grating.
9.3 Specification of the Multilayer Laminar–Type Grating.
9.4 Fabrication of Multilayer Laminar–Type Gratings.
9.5 Simulation of Diffraction Efficiency.
9.6 Measurement of Diffraction Efficiency.
9.7 Roughness Evaluation using Debye–Waller Factors.
References.
10 Nanostructuring of Thin–Film Surfaces in Femtosecond Laser Ablation (Kenzo Miyazaki).
10.1 Introduction.
10.2 Experimental.
10.3 Properties of Nanostructuring.
10.3.1 Polarization.
10.3.2 Multiple Pulses.
10.3.3 Fluence.
10.3.4 Laser Wavelength.
10.3.5 Pulse Width.
10.4 Bonding–Structure Change.
10.5 Dynamic Processes.
10.5.1 Reflectivity of Ablating Surface.
10.5.2 Ultrafast Dynamics.
10.6 Local Fields.
10.7 Origin of Periodicity.
10.8 Summary.
References.
11 Quantum Dot Nanophotonic Waveguides (Lih Y. Lin and Chia–Jean Wang).
11.1 Conceptual Formation and Modeling of the Device.
11.1.1 QD Gain vs. Pump Power.
11.1.2 FDTD Modeling for Interdot Coupling.
11.1.3 Monte Carlo Simulation for Transmission Efficiency.
11.2 From Concept to Realization – Fabrication of the Device.
11.2.1 DNA–Directed Self–Assembly Fabrication.
11.2.1.1 Self–Assembly Process and Characterization.
11.2.1.2 Programmable DNA–Directed Self–Assembly.
11.2.2 Self–Assembly Through APTES.
11.2.2.1 Self–Assembly Process and Characterization.
11.2.2.2 Multiple–QD–Type Waveguide Fabrication.
11.2.3 Discussion on Fabrication Methods.
11.3 How Well the Devices Work – A First Probe.
11.3.1 Waveguiding with Flexibility.
11.3.2 Loss Characterization.
11.4 To Probe Further – Summary and Outlook.
References.
12 Hierarchy in Optical Near–fields and its Application to Nanofabrication (Makoto Naruse, Takashi Yatsui, Hirokazu Hori, Kokoro Kitamura and Motoichi Ohtsu).
12.1 Introduction.
12.2 Angular Spectrum Representation of Optical Near–Fields.
12 .3 Generation of Smaller–Scale Structures via Optical Near–Fields: A Theoretical Basis.
12.4 Experiment.
12.5 Conclusion.
References.
Index.

Nota biograficzna:
Motoichi Ohtsu is professor of electrical engineering and information systems at the University of Tokyo, Japan. He obtained his engineering doctorate degree from the Tokyo Institute of Technology and began his scientific career there. Professor Ohtsu has authored over 410 scientific publications and holds 87 patents.
He is the author, co–author, and editor of 55 books, including 22 in English. He has received 14 scientific awards, comprising the Issac Koga Gold Medal of URSI, the Japan Royal Medal with a Purple Ribbon from the Japanese Government, and Distinguished Achievement Award from the IEICE of Japan. He is a member of the board of numerous committees in the Japanese government and Japanese and international academic societies as well as a fellow of the OSA.


Okładka tylna:
Starting out with a review of the principles of nanophotonics, this book covers a wide range of novel nanofabrication technologies. The internationally recognized editor pioneered this field of research and here he has gathered together a team of authors to highlight the technical details and procedures for both discrete particle as well as surface structure generation. They also illustrate the application potential of different materials, including biological, inorganic and artificial ones.
An invaluable monograph for materials scientists, chemists, physicists, telecommunications engineers, surface and physical chemists.
From the Contents:Principles and Practice of NanofabricationsNanofabrication by Self–Organization and Other Related TechnologiesFabrications of Quantum Dots and ZnO Nanorods for Nanophotonic DevicesLithography by NanophotonicsNanopatterned Media for High density Storage.Nanophotonics Re cording Device for High–Density StorageX–Ray Devices and the Possibility of Applying NanophotonicsFormation of Nanopatterns by Laser AblationQuantum Dot Nanophotonic WaveguidesHierarchy in Optical Near–Fields and its Application to Nanofabrication.