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Real-time observation of dissipative soliton formation in nonlinear polarization rotation mode-locked fibre lasers. / Peng, Junsong; Sorokina, Mariia; Sugavanam, Srikanth и др.

в: Communications Physics, Том 1, № 1, 20, 31.05.2018.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

Peng, J, Sorokina, M, Sugavanam, S, Tarasov, N, Churkin, DV, Turitsyn, SK & Zeng, H 2018, 'Real-time observation of dissipative soliton formation in nonlinear polarization rotation mode-locked fibre lasers', Communications Physics, Том. 1, № 1, 20. https://doi.org/10.1038/s42005-018-0022-7

APA

Peng, J., Sorokina, M., Sugavanam, S., Tarasov, N., Churkin, D. V., Turitsyn, S. K., & Zeng, H. (2018). Real-time observation of dissipative soliton formation in nonlinear polarization rotation mode-locked fibre lasers. Communications Physics, 1(1), [20]. https://doi.org/10.1038/s42005-018-0022-7

Vancouver

Peng J, Sorokina M, Sugavanam S, Tarasov N, Churkin DV, Turitsyn SK и др. Real-time observation of dissipative soliton formation in nonlinear polarization rotation mode-locked fibre lasers. Communications Physics. 2018 май 31;1(1):20. doi: 10.1038/s42005-018-0022-7

Author

Peng, Junsong ; Sorokina, Mariia ; Sugavanam, Srikanth и др. / Real-time observation of dissipative soliton formation in nonlinear polarization rotation mode-locked fibre lasers. в: Communications Physics. 2018 ; Том 1, № 1.

BibTeX

@article{c62e81beeaf14d4b8898bc2099df9ac9,
title = "Real-time observation of dissipative soliton formation in nonlinear polarization rotation mode-locked fibre lasers",
abstract = "Formation of coherent structures and patterns from unstable uniform state or noise is a fundamental physical phenomenon that occurs in various areas of science ranging from biology to astrophysics. Understanding of the underlying mechanisms of such processes can both improve our general interdisciplinary knowledge about complex nonlinear systems and lead to new practical engineering techniques. Modern optics with its high precision measurements offers excellent test-beds for studying complex nonlinear dynamics, though capturing transient rapid formation of optical solitons is technically challenging. Here we unveil the build-up of dissipative soliton in mode-locked fibre lasers using dispersive Fourier transform to measure spectral dynamics and employing autocorrelation analysis to investigate temporal evolution. Numerical simulations corroborate experimental observations, and indicate an underlying universality in the pulse formation. Statistical analysis identifies correlations and dependencies during the build-up phase. Our study may open up possibilities for real-time observation of various nonlinear structures in photonic systems.",
keywords = "ROGUE WAVES, MUTUAL INFORMATION, SPATIAL SOLITONS, DYNAMICS, FLUCTUATIONS, BREATHERS, STRETCH, STATE",
author = "Junsong Peng and Mariia Sorokina and Srikanth Sugavanam and Nikita Tarasov and Churkin, {Dmitry V.} and Turitsyn, {Sergei K.} and Heping Zeng",
year = "2018",
month = may,
day = "31",
doi = "10.1038/s42005-018-0022-7",
language = "English",
volume = "1",
journal = "Communications Physics",
issn = "2399-3650",
publisher = "Springer Nature",
number = "1",

}

RIS

TY - JOUR

T1 - Real-time observation of dissipative soliton formation in nonlinear polarization rotation mode-locked fibre lasers

AU - Peng, Junsong

AU - Sorokina, Mariia

AU - Sugavanam, Srikanth

AU - Tarasov, Nikita

AU - Churkin, Dmitry V.

AU - Turitsyn, Sergei K.

AU - Zeng, Heping

PY - 2018/5/31

Y1 - 2018/5/31

N2 - Formation of coherent structures and patterns from unstable uniform state or noise is a fundamental physical phenomenon that occurs in various areas of science ranging from biology to astrophysics. Understanding of the underlying mechanisms of such processes can both improve our general interdisciplinary knowledge about complex nonlinear systems and lead to new practical engineering techniques. Modern optics with its high precision measurements offers excellent test-beds for studying complex nonlinear dynamics, though capturing transient rapid formation of optical solitons is technically challenging. Here we unveil the build-up of dissipative soliton in mode-locked fibre lasers using dispersive Fourier transform to measure spectral dynamics and employing autocorrelation analysis to investigate temporal evolution. Numerical simulations corroborate experimental observations, and indicate an underlying universality in the pulse formation. Statistical analysis identifies correlations and dependencies during the build-up phase. Our study may open up possibilities for real-time observation of various nonlinear structures in photonic systems.

AB - Formation of coherent structures and patterns from unstable uniform state or noise is a fundamental physical phenomenon that occurs in various areas of science ranging from biology to astrophysics. Understanding of the underlying mechanisms of such processes can both improve our general interdisciplinary knowledge about complex nonlinear systems and lead to new practical engineering techniques. Modern optics with its high precision measurements offers excellent test-beds for studying complex nonlinear dynamics, though capturing transient rapid formation of optical solitons is technically challenging. Here we unveil the build-up of dissipative soliton in mode-locked fibre lasers using dispersive Fourier transform to measure spectral dynamics and employing autocorrelation analysis to investigate temporal evolution. Numerical simulations corroborate experimental observations, and indicate an underlying universality in the pulse formation. Statistical analysis identifies correlations and dependencies during the build-up phase. Our study may open up possibilities for real-time observation of various nonlinear structures in photonic systems.

KW - ROGUE WAVES

KW - MUTUAL INFORMATION

KW - SPATIAL SOLITONS

KW - DYNAMICS

KW - FLUCTUATIONS

KW - BREATHERS

KW - STRETCH

KW - STATE

UR - http://www.scopus.com/inward/record.url?scp=85060975980&partnerID=8YFLogxK

U2 - 10.1038/s42005-018-0022-7

DO - 10.1038/s42005-018-0022-7

M3 - Article

AN - SCOPUS:85060975980

VL - 1

JO - Communications Physics

JF - Communications Physics

SN - 2399-3650

IS - 1

M1 - 20

ER -

ID: 21345747