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Progress in Nanophotonics 1 2011 ed. [Hardback]

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  • Formāts: Hardback, 238 pages, height x width: 235x155 mm, weight: 547 g, XIV, 238 p., 1 Hardback
  • Sērija : Nano-Optics and Nanophotonics
  • Izdošanas datums: 29-Jul-2011
  • Izdevniecība: Springer-Verlag Berlin and Heidelberg GmbH & Co. K
  • ISBN-10: 3642174809
  • ISBN-13: 9783642174803
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Progress in Nanophotonics 1 2011 ed.Palielināt
  • Formāts: Hardback, 238 pages, height x width: 235x155 mm, weight: 547 g, XIV, 238 p., 1 Hardback
  • Sērija : Nano-Optics and Nanophotonics
  • Izdošanas datums: 29-Jul-2011
  • Izdevniecība: Springer-Verlag Berlin and Heidelberg GmbH & Co. K
  • ISBN-10: 3642174809
  • ISBN-13: 9783642174803
Citas grāmatas par šo tēmu:
Permanent link: https://www.kriso.lv/db/9783642174803.html
Keywords:
This book focuses on the recent progress in nanophotonics technology to be used to develop novel nano-optical devices, fabrication technology, and security systems. It begins with a review of the concept of dressed photons and applications to devices, fabrication, and systems; principles and applications. Further topics include: DNA process for quantum dot chain, photon enhanced emission microscopy, near field spectroscopy of metallic nanostructure, self-organized fabrication of composite semiconductor quantum dots, formation of metallic nanostructure, and nanophotonic information systems with security. These topics are reviewed by seven leading scientists. This overview is a variable resource for engineers and scientists working in the field of nanophotonics.

This book focuses on the recent progress in nanophotonics technology to be used to develop novel nano-optical devices, fabrication technology, and security systems. The topics covered are reviewed by seven leading scientists to provide a variable resource.
1 Nanophotonics: Dressed Photon Technology for Qualitatively Innovative Optical Devices, Fabrication, and Systems
1(58)
Motoichi Ohtsu
1.1 Introduction
1(1)
1.2 Background and Principles
2(4)
1.3 Fiber Probes, Sensing Systems, and 1 Tb in.--2-Density Magnetic Storage Systems
6(3)
1.4 Nanophotonic Devices
9(15)
1.4.1 Basic Devices
9(8)
1.4.2 Input and Output Terminals
17(3)
1.4.3 Unique Features and Application to Information Processing Systems
20(4)
1.5 Nanophotonic Fabrication
24(20)
1.5.1 Photochemical Vapor Deposition
24(4)
1.5.2 Photolithography
28(7)
1.5.3 Self-Organized Smoothing
35(9)
1.6 Nanophotonic Energy Conversion
44(9)
1.6.1 Optical/Optical Energy Up-Conversion
44(4)
1.6.2 Optical/Electrical Energy Up-Conversion
48(5)
1.7 Nanophotonic Systems and Their Evolution to Related Sciences
53(1)
1.8 Summary
54(1)
References
55(4)
2 Probe-Free Nanophotonic Systems: Macro-Scale Applications Based on Nanophotonics
59(34)
Naoya Tate
Makoto Naruse
Motoichi Ohtsu
2.1 Introduction
59(2)
2.2 Probe-Free Nanophotonic Systems
61(2)
2.3 Nanophotonic Matching as Macro-Scale Observation
63(9)
2.3.1 Macro-Scale Observation
63(1)
2.3.2 Quadrupole--Dipole Transform
63(2)
2.3.3 Nanophotonic Matching
65(2)
2.3.4 Experimental Demonstration
67(3)
2.3.5 Outlook
70(2)
2.4 Nanophotonics-Induced Phase Transition as Magnified-Transcription
72(5)
2.4.1 Magnified-Transcription of Optical Near-Fields
72(1)
2.4.2 Photoinduced Phase Transition
73(1)
2.4.3 Experimental Demonstrations
74(3)
2.4.4 Outlook
77(1)
2.5 Nanophotonic Hierarchical Hologram
77(13)
2.5.1 Background
77(1)
2.5.2 Basic Concept
78(3)
2.5.3 Nanophotonic Code
81(1)
2.5.4 Numerical Evaluations
82(3)
2.5.5 Experimental Demonstration
85(4)
2.5.6 Outlook
89(1)
2.6 Summary
90(1)
References
91(2)
3 Self-Formation of Semiconductor Quantum Dots
93(34)
Koichi Yamaguchi
3.1 Introduction
93(1)
3.2 Stranski--Krastaov Growth of Quantum Dots
94(2)
3.3 Uniform Formation of Quantum Dots
96(10)
3.3.1 Self Size-Limiting Growth of Uniform InAs/GaAs Quantum Dots
96(4)
3.3.2 Capping Growth of Uniform InAs/GaAs Quantum Dots
100(3)
3.3.3 Closely-Stacked Growth of Uniform InAs/GaAs Quantum Dots
103(3)
3.4 Control of Quantum Energy Level
106(3)
3.5 Density Control of Quantum Dots
109(7)
3.5.1 Sb-Mediated Growth of High-Density InAs/GaAs Quantum Dots
109(4)
3.5.2 Intermittent Growth of Low-Density InAs/GaAs Quantum Dots
113(3)
3.6 Quantum Dot Array
116(7)
3.6.1 Vertical Array of InAs/GaAs Quantum Dots
116(2)
3.6.2 In-Plane Arrays of InAs/GaAs Quantum Dots
118(5)
3.7 Conclusion
123(1)
References
123(4)
4 Near-Field Optical Imaging of Plasmon Wavefunctions and Optical Fields in Plasmonic Nanostructures
127(34)
Kohei Imura
Hiromi Okamoto
4.1 Introduction
127(1)
4.2 Optical Properties of Nanoparticles
128(5)
4.2.1 Optical Properties of Ensemble of Nanoparticles
131(2)
4.3 Plasmon Wavefunctions
133(1)
4.4 Principle of Wavefunction Visualization
133(2)
4.5 Near-Field Optical Microscope
135(3)
4.5.1 Instrumentation of Near-Field Optical Microscope
135(2)
4.5.2 Time-Resolved and Non-Linear Measurements
137(1)
4.6 Photonic Local Density-of-States Calculation
138(1)
4.7 Near-Field Transmission Measurements
139(6)
4.7.1 Near-Field Transmission Measurement of Spherical Gold Nanoparticles
140(1)
4.7.2 Near-Field Transmission Measurement of Gold Nanorods
141(104)
4.8 Time-Resolved Measurement
145(3)
4.9 Non-Linear Measurements
148(8)
4.9.1 Gold Nanorods
149(2)
4.9.2 Gold Nonoplates
151(1)
4.9.3 Dimeric Nanoparticles
152(2)
4.9.4 Larger Assemblies of Nanoparticles
154(2)
4.10 Summary
156(1)
References
157(4)
5 Simple Approaches for Constructing Metallic Nanoarrays on a Solid Surface
161(28)
Hidenobu Nakao
5.1 Introduction
161(1)
5.2 Assembling MNPs in One Dimension
162(4)
5.2.1 Chemical Self-Assembly
162(2)
5.2.2 Physical Means
164(2)
5.2.3 Template-Assisted Assembly
166(1)
5.3 Highly Aligned DNA as Templates for 1D Assembly of MNPs
166(10)
5.3.1 Stretching and Aligning DNA Molecules on Surfaces
167(3)
5.3.2 Assembling AuNPs onto Aligned DNA Molecules
170(6)
5.4 Fabrication and Patterning of Metallic Nanoarrays with Long-Range Order
176(6)
5.4.1 Preparation of Longer Metallic Nanoarrays with DNA Nanofibers
177(4)
5.4.2 Transfer Printing of Metallic Nanoarray
181(1)
5.5 Conclusions
182(2)
References
184(5)
6 Assembly and Immobilization of Metal Nanoparticles
189(44)
Nao Terasaki
Tetsu Yonezawa
6.1 Introduction
189(1)
6.2 Preparation of Metal Nanoparticles
190(4)
6.2.1 Preparation of Metal Nanoparticles by Chemical Reduction
190(4)
6.3 Assembly Formation
194(34)
6.3.1 Two Dimensional Assembly Formation of Nanoparticles by Simple Evaporation of Dispersions
195(2)
6.3.2 Two Dimensional Arrays Formation on Liquid-Liquid Interfaces
197(1)
6.3.3 Direct Preparation of Nanostructures on a Substrate
198(1)
6.3.4 Control of Nanoparticle Assembly by Stabilizing Reagents
198(8)
6.3.5 Nanoparticle Assembly with Templates
206(22)
6.4 Conclusions
228(1)
References
229(4)
Index 233
Motoiochi Ohtsu was appointed a Research Associate, an Associate professor, a Professor at the Tokyo Institute of Technology. From 1986 to 1987, while on leave from the Tokyo Institute of Technology, he joined the Crawford Hill Laboratory, AT&T Bell Laboratories, Holmdel, NJ. In 2004, he moved to the University of Tokyo as a professor. He has been the leader of the "Photon Control" project (1993-1998), the Kanagawa Academy of Science and Technology, Kanagawa, Japan), the "Localized Photon" project (1998-2003: ERATO,JST, Japan), "Terabyte Optical Storage Technology" project (2002-2006): NEDO, Japan), and "Near field optical lithography system" project (2004-2006: Ministry of Education, Japan),. He is concurrently the leader of the "Nanophotonics" team (2003-2009: SORST, JST, Japan), "Innovative Nanophotonics Components Development" project (2006-present: NEDO, Japan), and "Nanophotonics Total Expansion: Industry University Cooperation and "Human ResourceDevelopment" project (2006-present: NEDO, Japan).He has written over 417 papers and received 87 patents. He is the author, co-author, and editor of 55 books, including 22 in English.

In 2000, he was appointed as the President of the Tokyo Chapter, LEOS, IEEE. From 2000,

He is an executive director of the Japan Society of Applied Physics. His main field of interests is nanophotonics.

He is a Fellow of the Optical Society of America, and a Fellow of the Japan Society of Applied Physics. He is also a Tandem Member of the Science Council of Japan.

Awards: 14 prizes from academic institutions, including the Issac Koga Gold Medal of URSI in 1984, the Japan IBM Science Award in 1988, two awards from the Japan Society of Applied Physics in 1982 and 1990, the Inoue Science Foundation Award in 1999, the Japan Royal Medal with a Purple  Ribbon from the Japanese Government in 2004, H. Inoue Award from JST in 2005, the Distinguished Achievement Award from the Institute of Electronics,Information and Communication Engineering of Japan in 2007, the Julius Springer Prize for Applied Physics in 2009.