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Photonics, Volume 3: Photonics Technology and Instrumentation [Kõva köide]

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(University of Maryland, USA)
  • Formaat: Hardback, 544 pages, kõrgus x laius x paksus: 243x161x34 mm, kaal: 871 g
  • Sari: A Wiley-Science Wise Co-Publication
  • Ilmumisaeg: 24-Apr-2015
  • Kirjastus: John Wiley & Sons Inc
  • ISBN-10: 1118225546
  • ISBN-13: 9781118225547
Teised raamatud teemal:
Photonics, Volume 3: Photonics Technology and InstrumentationSuurem pilt
  • Formaat: Hardback, 544 pages, kõrgus x laius x paksus: 243x161x34 mm, kaal: 871 g
  • Sari: A Wiley-Science Wise Co-Publication
  • Ilmumisaeg: 24-Apr-2015
  • Kirjastus: John Wiley & Sons Inc
  • ISBN-10: 1118225546
  • ISBN-13: 9781118225547
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9781118225547.html
Märksõnad:
"The Handbook of Photonics third volume addresses photonics technology and application. It discusses communication networks, data buffers, defense and security applications, detectors, fiber optics and amplifiers, green photonics, instrumentation and metrology, interferometers, light-harvesting materials, logic devices, optical communications, remote sensing, solar energy, solid-state lighting, and wavelength conversion"--

Discusses the basic physical principles underlying the technology instrumentation of photonics

This volume discusses photonics technology and instrumentation. The topics discussed in this volume are: Communication Networks; Data Buffers; Defense and Security Applications; Detectors; Fiber Optics and Amplifiers; Green Photonics; Instrumentation and Metrology; Interferometers; Light-Harvesting Materials; Logic Devices; Optical Communications; Remote Sensing; Solar Energy; Solid-State Lighting; Wavelength Conversion

  • Comprehensive and accessible coverage of the whole of modern photonics
  • Emphasizes processes and applications that specifically exploit photon attributes of light
  • Deals with the rapidly advancing area of modern optics
  • Chapters are written by top scientists in their field

Written for the graduate level student in physical sciences; Industrial and academic researchers in photonics, graduate students in the area; College lecturers, educators, policymakers, consultants, Scientific and technical libraries, government laboratories, NIH.
List of Contributors ix
Preface xi
1 Solid-State Lighting: Toward Smart and Ultraefficient Materials, Devices, Lamps, and Systems 1(56)
M.H. Crawford
J.J. Wierer
A.J. Fischer
G.T. Wang
D.D. Koleske
G.S. Subramania
M.E. Coltrin
R.F. Karlicek Jr
J.Y. Tsao
1.1 A Brief History of SSL,
1(9)
1.2 Beyond the State-of-the-Art: Smart and Ultraefficient SSL,
10(11)
1.3 Ultraefficient SSL Lighting: Toward Multicolor Semiconductor Electroluminescence,
21(21)
1.4 Smart Solid-State Lighting: Toward Control of Flux and Spectra in Time and Space,
42(4)
1.5 Summary and Conclusions,
46(1)
Acknowledgments,
46(1)
References,
47(10)
2 Integrated Optics Using High Contrast Gratings 57(50)
Connie Chang-Hasnain
Weijian Yang
2.1 Introduction,
57(1)
2.2 Physics of Near-Wavelength Grating,
58(19)
2.3 Applications of HCGs,
77(21)
2.4 Summary,
98(1)
Acknowledgments,
98(1)
References,
98(9)
3 Plasmonic Crystals: Controlling Light with Periodically Structured Metal Films 107(62)
Wayne Dickson
Gregory A. Wurtz
Anatoly V. Zayats
3.1 Introduction,
107(3)
3.2 Surface Plasmon Polaritons,
110(3)
3.3 Basics of Surface Plasmon Polaritonic Crystals,
113(7)
3.4 Polarization and Wavelength Management with Plasmonic Crystals,
120(18)
3.5 Chirped Plasmonic Crystals: Broadband and Broadangle SPP Antennas Based on Plasmonic Crystals,
138(8)
3.6 Active Control of Light with Plasmonic Crystals,
146(14)
3.7 Conclusion,
160(1)
Acknowledgments,
160(1)
References,
160(9)
4 Optical Holography 169(46)
Raymond K. Kostuk
4.1 Introduction,
169(1)
4.2 Basic Concepts in Holography,
169(3)
4.3 Hologram Analysis,
172(10)
4.4 Hologram Geometries,
182(1)
4.5 Holographic Recording Materials,
183(5)
4.6 Digital Holography,
188(5)
4.7 Computer Generated Holography,
193(5)
4.8 Holographic Applications,
198(10)
References,
208(7)
5 Cloaking and Transformation Optics 215(38)
Martin W. McCall
5.1 Introduction,
215(2)
5.2 Theoretical Underpinning,
217(9)
5.3 The Carpet Cloak,
226(6)
5.4 Conformal Cloaking,
232(2)
5.5 Spacetime Cloaking,
234(9)
5.6 Conclusion and Outlook: Beyond Optics,
243(1)
Appendix 5.A: Technicalities,
244(1)
Appendix 5.B: Vectors and Tensors in Flat Spacetime,
245(2)
Appendix 5.C: Maxwell's Equations and Constitutive Relations in Covariant Form,
247(4)
References,
251(2)
6 Photonic Data Buffers 253(34)
S.J.B. Yoo
6.1 Introduction,
253(1)
6.2 Applications of Photonic Buffers,
254(4)
6.3 Limitations of Electronics,
258(2)
6.4 Photonic Buffer Technologies,
260(18)
6.5 Integration Efforts,
278(1)
6.6 Summary,
278(1)
References,
278(9)
7 Optical Forces, Trapping and Manipulation 287(54)
Halina Rubinsztein-Dunlop
Alexander B. Stilgoe
Darryl Preece
Ann Bui
Timo A. Nieminen
7.1 Introduction,
287(6)
7.2 Theory of Optical Forces,
293(8)
7.3 Theory of Optical Torques,
301(7)
7.4 Measurement of Forces and Torques,
308(10)
7.5 Calculation of Forces and Torques,
318(11)
7.6 Conclusion,
329(1)
References,
329(12)
8 Optofluidics 341(28)
Lin Pang
H. Matthew Chen
Lindsay M. Freeman
Yeshaiahu Fainman
8.1 Introduction,
341(1)
8.2 Photonics with Fluid Manipulation,
342(8)
8.3 Fluidic Sensing,
350(3)
8.4 Fluidic Enabled Imaging,
353(5)
8.5 Fluid Assisted Nanopatterning,
358(3)
8.6 Conclusions and Outlook,
361(1)
Acknowledgments,
362(1)
References,
362(7)
9 Nanoplasmonic Sensing for Nanomaterials Science 369(34)
Elfin M. Larsson-Langhammer
Svetlana Syrenova
Christoph Langhammer
9.1 Introduction,
369(1)
9.2 Nanoplasmonic Sensing and Readout,
370(3)
9.3 Inherent Limitations of Nanoplasmonic Sensors,
373(1)
9.4 Direct Nanoplasmonic Sensing,
373(1)
9.5 Indirect Nanoplasmonic Sensing,
374(2)
9.6 Overview on Different Examples,
376(20)
9.7 Discussion and Outlook,
396(1)
References,
397(6)
10 Laser Fabrication and Nanostructuring 403(42)
Cemal Esen
Andreas Ostendorf
10.1 Introduction,
403(1)
10.2 Laser Systems for Nanostructuring,
404(5)
10.3 Surface Structuring by Laser Ablation,
409(7)
10.4 Generation of thin Films by Laser Ablation in Vacuum,
416(3)
10.5 Generation of Nanoparticles by Laser Ablation in Liquids,
419(4)
10.6 Laser Induced Volume Structures,
423(3)
10.7 Direct Writing of Polymer Components via Two-Photon Polymerization,
426(5)
10.8 Conclusion,
431(1)
References,
432(13)
11 Free Electron Lasers for Photonics Technology by Wiley 445(32)
George R. Neil
Gwyn P. Williams
11.1 Introduction,
445(1)
11.2 Physical Principles,
446(16)
11.3 Worldwide FEL Status,
462(4)
11.4 Applications,
466(5)
11.5 Summary and Conclusion,
471(1)
References,
471(6)
Index 477
David L. Andrews leads research on fundamental molecular photonics and energy transport, optomechanical forces and nonlinear optical phenomena. He has over 160 research papers and also eight books to his name - including the widely adopted textbook Lasers in Chemistry. The current focus of his research group is on novel mechanisms for optical nanomanipulation and switching, and light-harvesting in nanostructured molecular systems. The group enjoys strong international links, particularly with groups in Canada, Lithuania, New Zealand and the United States. Andrews is a Fellow of the Royal Society of Chemistry, and a Fellow of the Institute of Physics, and he is the inaugural Chair of the SPIE Nanotechnology Technical Group.