Nonlinear guided wave optics : a testbed for extreme waves /

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Bibliographic Details
Imprint:Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) : IOP Publishing, [2017]
Description:1 online resource (various pagings) : illustrations (some color).
Language:English
Series:[IOP release 4]
IOP expanding physics, 2053-2563
Series in emerging technologies in optics and photonics
IOP (Series). Release 4.
IOP expanding physics.
Series in emerging technologies in optics and photonics.
Subject:
Format: E-Resource Book
URL for this record:http://pi.lib.uchicago.edu/1001/cat/bib/11432388
Hidden Bibliographic Details
Other authors / contributors:Wabnitz, S., editor.
Institute of Physics (Great Britain), publisher.
ISBN:9780750314602
9780750314596
9780750314589
Notes:"Version: 20171201"--Title page verso.
Includes bibliographical references.
Also available in print.
System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.
Stefan Wabnitz obtained the Laurea Degree in Electronics Engineering from the University of Rome 'La Sapienza' in 1982, the MS in Electrical Engineering from Caltech in 1983, and the PhD in Applied Electromagnetism from the Italian Ministry of Education in 1988. He was with the Ugo Bordoni Foundation between 1985 and 1996. In 1996 he became full professor in Physics at the University of Burgundy in Dijon, France. Between 1999 and 2003 he was with Alcatel Research and Innovation Labs in France and with Xtera Communications in Texas. Since 2007 he has been full professor the Department of Information Engineering of the University of Brescia, Italy. His research activities involve nonlinear propagation effects in optical communications and information processing devices. He is the author and co-author of over 700 international refereed papers, conference presentations, and book chapters. He is the Deputy Editor of the Elsevier journal Optical Fiber Technology, a Fellow member of the Optical Society of America, and senior member of IEEE-Photonics Society.
Title from PDF title page (viewed on January 11, 2018).
Summary:Experiments and theory have rapidly progressed on nonlinear optical extreme waves, showing that guided wave nonlinear optics and fiber lasers provide a relatively simple, accessible and controllable test bed for the observations and accurate statistical studies of extreme wave phenomena that obey the same universal rules, which apply to a large ensemble of different physical systems. With introductory material to make the subject area accessible to non-specialists such as graduate and PhD students, and researchers working in other areas where extreme waves are relevant, this book features contributions by prominent scientists in this emerging field and is a comprehensive treatment of optical extreme wave research.
Target Audience:Advanced students and researchers working in nonlinear optics.
Other form:Print version: 9780750314589
Standard no.:10.1088/978-0-7503-1460-2

MARC

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300 |a 1 online resource (various pagings) :  |b illustrations (some color). 
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490 1 |a Series in emerging technologies in optics and photonics 
500 |a "Version: 20171201"--Title page verso. 
504 |a Includes bibliographical references. 
505 0 |a 1. Extreme events in forced oscillatory media in zero, one and two dimensions -- 1.1. Introduction -- 1.2. Zero dimensions -- 1.3. One dimension -- 1.4. Two dimensions -- 1.5. Conclusion 
505 8 |a 2. Extreme waves in stimulated backscattering and frequency conversion processes -- 2.1. Introduction -- 2.2. Fundamental rogue wave solutions -- 2.3. Higher-order rogue wave solutions -- 2.4. Rogue wave solutions in the degenerate case -- 2.5. Rogue wave existence and baseband MI -- 2.6. Numerical simulations -- 2.7. Conclusions 
505 8 |a 3. Irreversibility and squeezing of shock waves -- 3.1. Introduction -- 3.2. Hydrodynamic approximation of dispersive shock waves -- 3.3. Highly non-local limit and irreversibility -- 3.4. Squeezing -- 3.5. Conclusions 
505 8 |a 4. Observation of the rupture of a photon dam in an optical fiber -- 4.1. Introduction -- 4.2. Theory of classic and dispersive dam breaking -- 4.3. Experiment -- 4.4. Conclusions 
505 8 |a 5. Instabilities and extreme events in all-normal dispersion mode-locked fibre lasers -- 5.1. Introduction -- 5.2. All-normal dispersion mode-locked fibre lasers -- 5.3. Stable mode-locking -- 5.4. Noise-like emission -- 5.5. Real-time measurements and extreme Raman fluctuations -- 5.6. Soliton explosions -- 5.7. Metastable dark solitons in radiation build-up dynamics -- 5.8. Conclusions 
505 8 |a 6. Extreme wave dynamics from incoherent dissipative solitons in fiber laser cavities -- 6.1. Introduction : the notion of incoherent dissipative solitons -- 6.2. Dissipative rogue waves from chaotic pulse bunching -- 6.3. Extreme vector waves -- 6.4. Conclusions 
505 8 |a 7. Ubiquitous nature of modulation instability : from periodic to localized perturbations -- 7.1. Introduction -- 7.2. Breather formalism -- 7.3. Experimental demonstrations -- 7.4. Localized noise-driven modulation instability -- 7.5. Conclusions 
505 8 |a 8. Rogue waves in photorefractive media -- 8.1. Introduction -- 8.2. Spatial rogue waves in photorefractive ferroelectrics -- 8.3. Optical instabilities and strong wave turbulence -- 8.4. Incoherence, saturation, and solitons in extreme waves -- 8.5. Future developments 
505 8 |a 9. Vector rogue waves driven by polarisation instabilities -- 9.1. Introduction -- 9.2. Bright and dark rogue waves in mode-locked fibre laser -- 9.3. Synchronisation and desynchronisation phenomena in a long cavity Er-doped fibre laser -- 9.4. Summary 
505 8 |a 10. Fundamental rogue waves and their superpositions in nonlinear integrable systems -- 10.1. Introduction -- 10.2. NLSE rogue waves -- 10.3. Splitting of higher-order rogue waves -- 10.4. Extended equation -- 10.5. Integrable extensions -- 10.6. Infinitely long NLSE extensions -- 10.7. Conclusions 
505 8 |a 11. Are rogue waves really rogue? -- 11.1. Introduction -- 11.2. Definition of rogue waves : predictability -- 11.3. Rogue waves in the multi-filament scenario -- 11.4. Comparison of the three different rogue wave supporting systems -- 11.5. Filament rogue waves -- 11.6. Predictability of rogue waves -- 11.7. Conclusion 
505 8 |a 12. Rogue waves in integrable turbulence : semi-classical theory and fast measurements -- 12.1. Introduction -- 12.2. Semi-classical limit of focusing 1D-NLSE and rogue waves -- 12.3. Integrable turbulence and the inverse scattering transform method -- 12.4. Experiments in optical fibers -- 12.5. Conclusion 
505 8 |a 13. Rogue wave formation in highly birefringent fiber -- 13.1. Introduction -- 13.2. Model and linear stability analysis -- 13.3. Statistical analysis of the RW in the highly birefringent fiber -- 13.4. Results in the normal dispersion regime -- 13.5. Results in a normal dispersion -- 13.6. Conclusion 
505 8 |a 14. Spatiotemporal nonlinear dynamics in multimode fibers -- 14.1. Introduction -- 14.2. Spatial beam self-cleaning -- 14.3. Theoretical models of spatiotemporal dynamics -- 14.4. Spatiotemporal instabilities -- 14.5. Supercontinuum generation 
505 8 |a 15. Noise-initiated dynamics in nonlinear fiber optics -- 15.1. Introduction -- 15.2. Modulation instability and breather solutions -- 15.3. Noise-driven modulation instability -- 15.4. Measuring chaotic dynamics in real time -- 15.5. Conclusions 
505 8 |a 16. Cavity soliton dynamics and rogue waves in driven Kerr cavities -- 16.1. Introduction -- 16.2. Spatiotemporal chaos in Lugiato-Lefever model -- 16.3. Cavity soliton dynamics and rogue waves in the delayed LLE -- 16.4. Conclusions. 
520 3 |a Experiments and theory have rapidly progressed on nonlinear optical extreme waves, showing that guided wave nonlinear optics and fiber lasers provide a relatively simple, accessible and controllable test bed for the observations and accurate statistical studies of extreme wave phenomena that obey the same universal rules, which apply to a large ensemble of different physical systems. With introductory material to make the subject area accessible to non-specialists such as graduate and PhD students, and researchers working in other areas where extreme waves are relevant, this book features contributions by prominent scientists in this emerging field and is a comprehensive treatment of optical extreme wave research. 
521 |a Advanced students and researchers working in nonlinear optics. 
530 |a Also available in print. 
538 |a System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader. 
545 |a Stefan Wabnitz obtained the Laurea Degree in Electronics Engineering from the University of Rome 'La Sapienza' in 1982, the MS in Electrical Engineering from Caltech in 1983, and the PhD in Applied Electromagnetism from the Italian Ministry of Education in 1988. He was with the Ugo Bordoni Foundation between 1985 and 1996. In 1996 he became full professor in Physics at the University of Burgundy in Dijon, France. Between 1999 and 2003 he was with Alcatel Research and Innovation Labs in France and with Xtera Communications in Texas. Since 2007 he has been full professor the Department of Information Engineering of the University of Brescia, Italy. His research activities involve nonlinear propagation effects in optical communications and information processing devices. He is the author and co-author of over 700 international refereed papers, conference presentations, and book chapters. He is the Deputy Editor of the Elsevier journal Optical Fiber Technology, a Fellow member of the Optical Society of America, and senior member of IEEE-Photonics Society. 
588 0 |a Title from PDF title page (viewed on January 11, 2018). 
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