Modulational instability: Difference between revisions

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Line 1: {{short description\|~~A phenomenon~~Phenomenon whereby deviations from a periodic waveform are reinforced by nonlinearity}} In the fields of [[nonlinear optics]] and [[fluid dynamics]], '''modulational instability''' or '''sideband instability''' is a phenomenon whereby deviations from a periodic waveform are reinforced by nonlinearity, leading to the generation of [[Frequency spectrum\|spectral]]-sidebands and the eventual breakup of the waveform into a train of [[wave packet\|pulses]].<ref name="BenjaminFeir">{{cite journal \| doi = 10.1017/S002211206700045X Line 13: \| journal = Journal of Fluid Mechanics \| year = 1967 \|bibcode = 1967JFM....27..417B \| s2cid = 121996479 }}</ref><ref>{{Cite journal \| doi = 10.1098/rspa.1967.0123 \| volume = 299 Line 25 ⟶ 26: \| series = A. Mathematical and Physical Sciences \| year = 1967 \|bibcode = 1967RSPSA.299...59B \| s2cid = 121661209 }} Concluded with a discussion by [[Klaus Hasselmann]].</ref><ref name="agrawal">{{cite book \| last = Agrawal \| first = Govind P. Line 47 ⟶ 49: \| journal = Annual Review of Fluid Mechanics \| year = 1980 \|bibcode = 1980AnRFM..12..303Y }}</ref> Therefore, it is also known as the '''Benjamin−Feir instability'''. However, spatial modulation instability of high-power lasers in organic solvents was observed by Russian scientists N. F. Piliptetskii and A. R. Rustamov in 1965,<ref>{{Cite journal\|~~last~~last1=Piliptetskii\|~~first~~first1=N. F.\|last2=Rustamov\|first2=A. R.\|date=31 May 1965\|title=Observation of Self-focusing of Light in Liquids\|url=http://www.jetpletters.ac.ru/ps/1596/article_24469.shtml\|journal=JETP Letters\|volume=2\|issue=2\|pages=~~55-56~~55–56}}</ref> and the mathematical derivation of modulation instability was published by V. I. Bespalov and V. I. Talanov in 1966.<ref>{{Cite journal\|~~last~~last1=Bespalov\|~~first~~first1=V. I.\|last2=Talanov\|first2=V. I.\|date=15 June 1966\|title=Filamentary Structure of Light Beams in Nonlinear Liquids\|url=http://www.jetpletters.ac.ru/ps/1621/article_24803.shtml\|journal=ZhETF ~~Pis ma~~Pisma Redaktsiiu\|volume=3\|issue=11\|pages=~~471~~471–476\|bibcode=1966ZhPmR...3..471B\|access-~~476~~date=17 February 2021\|archive-date=31 July 2020\|archive-url=https://web.archive.org/web/20200731112029/http://www.jetpletters.ac.ru/ps/1621/article_24803.shtml\|url-status=dead}}</ref> Modulation instability is a possible mechanism for the generation of [[rogue wave]]s.<ref>{{Cite journal \| doi = 10.1175/1520-0485(2003)33<863:NFIAFW>2.0.CO;2 \| volume = 33 Line 57 ⟶ 59: \| journal = Journal of Physical Oceanography \| year = 2003 \|bibcode = 2003JPO....33..863J \| doi-access = free }}</ref><ref>{{Cite journal \| doi = 10.1146/annurev.fluid.40.111406.102203 \| volume = 40 Line 75 ⟶ 78: ==Initial instability and gain== Modulation instability only happens under certain circumstances. The most important condition is ''anomalous group velocity [[dispersion relation\|dispersion]]'', whereby pulses with shorter [[wavelength]]s travel with higher [[group velocity]] than pulses with longer wavelength.<ref name="agrawal" /> (This condition assumes a ''~~focussing~~focusing'' [[Kerr nonlinearity]], whereby refractive index increases with optical intensity.)<ref name="agrawal" /> The instability is strongly dependent on the frequency of the perturbation. At certain frequencies, a perturbation will have little effect, ~~whilst~~while at other frequencies, a perturbation will [[exponential growth\|grow exponentially]]. The overall [[Gain (electronics)\|gain]] spectrum can be derived [[Analytical expression\|analytically]], as is shown below. Random perturbations will generally contain a broad range of frequency components, and so will cause the generation of spectral sidebands which reflect the underlying gain spectrum. The tendency of a perturbing signal to grow makes modulation instability a form of [[amplifier\|amplification]]. By tuning an input signal to a peak of the gain spectrum, it is possible to create an [[optical amplifier]]. Line 83 ⟶ 86: ===Mathematical derivation of gain spectrum=== The gain spectrum can be derived <ref name="agrawal" /> by starting with a model of modulation instability based upon the [[nonlinear Schrödinger equation]]{{what\|reason=Time and space reversed?\|date=February 2024}} : <math>\frac{\partial A}{\partial z} + i\beta_2\frac{\partial^2A}{\partial t^2} = i\gamma\|A\|^2A,</math> Line 122 ⟶ 125: == Modulation instability in soft systems == Modulation instability of optical fields has been observed in photo-chemical systems, namely, photopolymerizable medium.<ref>{{Cite journal\|~~last~~last1=Burgess\|~~first~~first1=Ian B.\|last2=Shimmell\|first2=Whitney E.\|last3=Saravanamuttu\|first3=Kalaichelvi\|date=2007-04-01\|title=Spontaneous Pattern Formation Due to Modulation Instability of Incoherent White Light in a Photopolymerizable Medium\|journal=Journal of the American Chemical Society\|volume=129\|issue=15\|pages=4738–4746\|doi=10.1021/ja068967b\|pmid=17378567\|bibcode=2007JAChS.129.4738B \|issn=0002-7863}}</ref><ref>{{Cite journal\|~~last~~last1=Basker\|~~first~~first1=Dinesh K.\|last2=Brook\|first2=Michael A.\|last3=Saravanamuttu\|first3=Kalaichelvi\|title=Spontaneous Emergence of Nonlinear Light Waves and Self-Inscribed Waveguide Microstructure during the Cationic Polymerization of Epoxides\|journal=The Journal of Physical Chemistry C\|language=en\|volume=119\|issue=35\|pages=20606–20617\|doi=10.1021/acs.jpcc.5b07117\|year=2015}}</ref><ref>{{Cite journal\|~~last~~last1=Biria\|~~first~~first1=Saeid\|last2=Malley\|first2=Philip P. A.\|last3=Kahan\|first3=Tara F.\|last4=Hosein\|first4=Ian D.\|date=2016-03-03\|title=Tunable Nonlinear Optical Pattern Formation and Microstructure in Cross-Linking Acrylate Systems during Free-Radical Polymerization\|journal=The Journal of Physical Chemistry C\|volume=120\|issue=8\|pages=4517–4528\|doi=10.1021/acs.jpcc.5b11377\|issn=1932-7447}}</ref><ref>{{Cite journal\|~~last~~last1=Biria\|~~first~~first1=Saeid\|last2=Malley\|first2=Phillip P. A.\|last3=Kahan\|first3=Tara F.\|last4=Hosein\|first4=Ian D.\|date=2016-11-15\|title=Optical Autocatalysis Establishes Novel Spatial Dynamics in Phase Separation of Polymer Blends during Photocuring\|journal=ACS Macro Letters\|volume=5\|issue=11\|pages=1237–1241\|doi=10.1021/acsmacrolett.6b00659\|pmid=35614732 }}</ref> Modulation instability occurs owing to inherent optical nonlinearity of the systems due to photoreaction-induced changes in the refractive index.<ref>{{Cite journal\|~~last~~last1=Kewitsch\|~~first~~first1=Anthony S.\|last2=Yariv\|first2=Amnon\|date=1996-01-01\|title=Self-focusing and self-trapping of optical beams upon photopolymerization\|journal=Optics Letters\|language=EN\|volume=21\|issue=1\|pages=24–6\|doi=10.1364/ol.21.000024\|issn=1539-4794\|bibcode=1996OptL...21...24K\|url=https://authors.library.caltech.edu/2845/1/KEWol96.pdf\|pmid=19865292}}</ref> Modulation instability of spatially and temporally incoherent light is possible owing to the non-instantaneous response of photoreactive systems, which consequently responds to the time-average intensity of light, in which the femto-second fluctuations cancel out.<ref>{{Cite book\|url=https://www.springer.com/us/book/9783540416531\|title=Spatial Solitons {{!}} Stefano Trillo {{!}} Springer\|language=en}}</ref> ==References== Line 150 ⟶ 153: [[Category:Photonics]] [[Category:Water waves]] [[Category:Fluid dynamic ~~instability~~instabilities]]