Atjaunināt sīkdatņu piekrišanu

E-grāmata: Progress in Nanophotonics 4

Edited by , Edited by
  • Formāts: EPUB+DRM
  • Sērija : Nano-Optics and Nanophotonics
  • Izdošanas datums: 18-Feb-2017
  • Izdevniecība: Springer International Publishing AG
  • Valoda: eng
  • ISBN-13: 9783319490137
Citas grāmatas par šo tēmu:
  • Formāts - EPUB+DRM
  • Cena: 53,52 €*
  • * ši ir gala cena, t.i., netiek piemērotas nekādas papildus atlaides
  • Ielikt grozā
  • Pievienot vēlmju sarakstam
  • Šī e-grāmata paredzēta tikai personīgai lietošanai. E-grāmatas nav iespējams atgriezt un nauda par iegādātajām e-grāmatām netiek atmaksāta.
Progress in Nanophotonics 4Palielināt
  • Formāts: EPUB+DRM
  • Sērija : Nano-Optics and Nanophotonics
  • Izdošanas datums: 18-Feb-2017
  • Izdevniecība: Springer International Publishing AG
  • Valoda: eng
  • ISBN-13: 9783319490137
Citas grāmatas par šo tēmu:

DRM restrictions

  • Kopēšana (kopēt/ievietot):

    nav atļauts

  • Drukāšana:

    nav atļauts

  • Lietošana:

    Digitālo tiesību pārvaldība (Digital Rights Management (DRM))
    Izdevējs ir piegādājis šo grāmatu šifrētā veidā, kas nozīmē, ka jums ir jāinstalē bezmaksas programmatūra, lai to atbloķētu un lasītu. Lai lasītu šo e-grāmatu, jums ir jāizveido Adobe ID. Vairāk informācijas šeit. E-grāmatu var lasīt un lejupielādēt līdz 6 ierīcēm (vienam lietotājam ar vienu un to pašu Adobe ID).

    Nepieciešamā programmatūra
    Lai lasītu šo e-grāmatu mobilajā ierīcē (tālrunī vai planšetdatorā), jums būs jāinstalē šī bezmaksas lietotne: PocketBook Reader (iOS / Android)

    Lai lejupielādētu un lasītu šo e-grāmatu datorā vai Mac datorā, jums ir nepieciešamid Adobe Digital Editions (šī ir bezmaksas lietotne, kas īpaši izstrādāta e-grāmatām. Tā nav tas pats, kas Adobe Reader, kas, iespējams, jau ir jūsu datorā.)

    Jūs nevarat lasīt šo e-grāmatu, izmantojot Amazon Kindle.

This book presents the recent progress in the field of nanophotonics. It contains review-like chapters focusing on various but mutually related topics in nanophotonics written by the world"s leading scientists. Following the elaboration of the idea of nanophotonics, much theoretical and experimental work has been carried out, and several novel photonic devices, high-resolution fabrication, highly efficient energy conversion, and novel information processing have been developed in these years. Novel theoretical models describing the nanometric light-matter interaction, nonequilibrium statistical mechanical models for photon breeding processes and near-field-assisted chemical reactions as well as light-matter interaction are also explained in this book. It describes dressed photon technology and its applications, including implementation of nanophotonic devices and systems, fabrication methods and performance characteristics of ultrathin, ultraflexible organic light-emitting diodes,

organic solar cells and organic transistors.

Progress in dressed photon technology and the future.- Nonequilibrium statistical mechanical models for photon breeding processes assisted by dressed-photon-phonons.- Nearfield-assisted chemical reactions and its applications.- Nanophotonics-based self-optimization for macro-optical applications.- Ultraflexible organic electronics and photonics.
1 Progress in Dressed Photon Technology and the Future
1(18)
Motoichi Ohtsu
1.1 Introduction
1(3)
1.2 The Dressed Photon as a Physical Picture of an Off-Shell Photon
4(2)
1.3 Applications of Dressed Photons
6(9)
1.3.1 Optical Functional Devices
7(1)
1.3.2 Nano-fabrication
7(1)
1.3.3 Energy Conversion
8(1)
1.3.4 Photon Breeding Devices
9(3)
1.3.5 Information Processing Systems
12(1)
1.3.6 Novel Theoretical Models and Future Outlook
13(2)
1.4 Summary
15(4)
References
16(3)
2 Nonequilibrium Statistical Mechanical Models for Photon Breeding Processes Assisted by Dressed-Photon-Phonons
19(38)
Makoto Katori
Hirotsugu Kobayashi
2.1 Introduction
19(4)
2.2 Experimental Results
23(3)
2.2.1 Si-LED
23(3)
2.2.2 GaP-LED
26(1)
2.3 Stochastic Models on Lattices
26(6)
2.3.1 Discrete Setting of Space and Time
27(1)
2.3.2 Random Walks of B Atoms Induced by I
27(1)
2.3.3 Elementary Processes of Photon Breeding
28(4)
2.3.4 Aging of δ-Pairs and Re-activation of B Atoms by Excess Heat
32(1)
2.4 Simulation for Fabrication and Operation of Si-LED
32(9)
2.4.1 Four Regimes of Simulated Processes
32(4)
2.4.2 Cooling of System in Transient Regime of Fabrication Process
36(1)
2.4.3 Construction of δ-Pair Network in Equilibrium Regime of Fabrication Process
37(3)
2.4.4 Accumulation of Excess Energy in Operation Process
40(1)
2.5 Optimization of DPP-Assisted Annealing by Ratio P0/2I
41(3)
2.5.1 Mean Emission Powers Versus P0/2I
41(1)
2.5.2 Lifetime of LED
41(3)
2.6 Light Polarization Controlled in Photon Breeding
44(5)
2.6.1 The Cases φ = 0 and π/2
44(1)
2.6.2 The Case φ = π/6
44(5)
2.7 Spectrum of Light Controlled in Photon Breeding
49(3)
2.8 Future Problems
52(5)
References
54(3)
3 Near-Field Assisted Chemical Reactions and Its Applications
57(30)
Takashi Yatsui
Katsuyuki Nobusada
3.1 Optical Near-Field---Nonuniform Electric-Field Distribution
57(1)
3.2 Near-Field Assisted Energy Upconversion
58(9)
3.2.1 Hydrogen Generation
58(4)
3.2.2 CO2 Reduction
62(5)
3.3 Near-Field Etching
67(16)
3.3.1 Flat Surface
69(6)
3.3.2 Three Dimensional Structures
75(2)
3.3.3 Polarization Dependence
77(6)
3.4 Summary
83(4)
References
84(3)
4 Nanophotonics-Based Self-optimization for Macro-optical Applications
87(36)
Naoya Tate
4.1 Introduction
87(4)
4.1.1 Self-assembly for Nanometric-Fabrication
87(1)
4.1.2 Nanophotonics for Self-assembly
88(3)
4.2 Nanophotonic Droplet
91(18)
4.2.1 Nanometric Alignment for Optical Energy Transfer
91(1)
4.2.2 Size Resonance-Based Nanometric Coupling
92(1)
4.2.3 Phonon-assisted Photo-Curing Process
93(3)
4.2.4 Experimental Demonstrations
96(5)
4.2.5 Dynamics of the Coupling Process
101(4)
4.2.6 High-Yield Optical Energy Conversion
105(3)
4.2.7 Further Discussions
108(1)
4.3 Optical Annealing-Based Electrooptical Device
109(11)
4.3.1 General Fabrication of Oxide Semiconductor
109(2)
4.3.2 Phonon-Assisted Optical Annealing
111(1)
4.3.3 Device Fabrication
111(2)
4.3.4 Demonstration as Polarization Rotator
113(3)
4.3.5 Demonstration as Optical Switching
116(4)
4.4 Summary
120(3)
References
121(2)
5 Ultraflexible Organic Electronics and Photonics
123(20)
Tsuyoshi Sekitani
5.1 Introduction
123(1)
5.2 Background and Purpose of Research
124(1)
5.3 Ultrathin Organic LEDs
125(2)
5.4 Ultrathin Organic Solar Cells (Optical Sensors or Photodetector)
127(1)
5.5 Ultrathin Organic Thin Film Transistors (TFTs)
128(7)
5.6 Development of Flexible Displays
135(3)
5.7 Future Prospects
138(5)
References
140(3)
Index 143
Motoichi Ohtsu was professor at the Tokyo Institute of Technology, Graduate School of Interdisciplinary Science and Engineering, from 1991 to 2004. He has been Director at the Nanophotonics Research Center of the University of Tokyo since 2008. In addition, he has been a professor at the Department of Electronics Engineering, Graduate School of Engineering, of the University of Tokyo since 2004. Prof. Takashi Yatsui got the Dr. degree in electronics engineering from Tokyo Inst. Tech. in 2000. He was employed as  a researcher at Japan Science and Technology Agency (20002008), and as associate professor at Univ. Tokyo since 2008. For his excellent research he got awards from the JSAP (2000), Tejima Doctoral Dissertation Award (2001), the Gottfried Wagener Prize (2011), Osaka University Kondo Prize (2012), Erlangen Innovation Award Optical Technologies (2012), The Ichimura Prize in Science for Distinguished Achievement (2016).
Biežāk uzdotie jautājumi par e-grāmatām Biežāk uzdotie jautājumi par e-grāmatām
Permanent link: https://www.kriso.lv/db/97833194901376e.html
Keywords: