FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2059673913> ?p ?o ?g. }

• W2059673913 abstract "Summary form only given. Dispersive wave (DW) generation in microstructured optical fibers (MOFs) is a hotly debated topic in supercontinuum generation. DWs are a typical outcome of strong nonlinear wave interactions, however their spectral positions are mainly ruled by the linear dispersive properties of the fiber: DWs appear at those spectral positions where wavevectors of DWs and soliton-like pulses are matched [1]. In this work we experimentally and numerically discuss how super-bright sideband generation around 1550 nm can be achieved in dual concentric core MOF (DCC-MOF) with long pulses typically delivered by subnanosecond lasers working in the near infrared. Strong conversion efficiencies (up to 30% of the injected input power) were observed thanks to the exotic guiding properties of these DCC-MOFs [2]. Differently from conventional MOFs, whose dispersion is in general anomalous in the optical communications band, the linear coupling of DCC-MOF drastically changes the guiding properties of the fundamental mode, thus causing an abrupt variation of the group delay between the pumping and the DW generation spectral regions. In this work we emphasize the role of group velocity difference between DWs and solitons. For this reason we have carried out a time-resolved spectral analysis of the supercontinuum generated by a 4-m long DCC-MOF by combining a diffractive grating and a single-slit giving a spectral resolution of 6 nm, and two 12.5 GHz bandwidth photodiodes. The laser pump was a microchip laser with pulse duration of 900 ps at 1064 nm and 4 kW peak power. We show on the left panel of Fig. 1 the pulse-width measured at different spectral regions (finest temporal structures cannot be unveiled with this method). We observe a negative time delay for the pulse center of mass when moving the 6 nm spectral window toward the infrared side, which qualitatively agrees well with the theoretical group delay and it is confirmed by our numerical predictions. In our DCC-MOF the DW overtakes the supercontinuum between 1064 nm and 1200 nm, in striking contrast with the case of single-core conventional MOFs, where the infrared part of the spectrum is in the trailing edge of the pulse envelope. Another key point discussed in the present work is the role of pump wavelength and pulse duration. On the top right panel of Fig. 1 we show the spectrum obtained with the 1064 nm microchip laser: an intense and spectrally wide DW around 1575 nm is easily recognized. Whereas the spectrum in the bottom right panel was obtained with a mode-locked laser emitting 120 ps pulses at 1030 nm. The pulse peak power had the same order of magnitude in both cases. In this case the DW is shifted towards 1505 nm, and its maximum spectral density is about 20 dB lower than in the previous case. Numerical simulations confirm the formation of the DW starting from the solitons bunch generated by the quasi-CW pump pulse break-up." @default.
• W2059673913 created "2016-06-24" @default.
• W2059673913 creator A5004452860 @default.
• W2059673913 creator A5005986416 @default.
• W2059673913 creator A5024413079 @default.
• W2059673913 creator A5030271091 @default.
• W2059673913 creator A5035979112 @default.
• W2059673913 creator A5062232002 @default.
• W2059673913 creator A5068254460 @default.
• W2059673913 creator A5069698573 @default.
• W2059673913 creator A5078506141 @default.
• W2059673913 creator A5079502813 @default.
• W2059673913 creator A5079996430 @default.
• W2059673913 creator A5082449437 @default.
• W2059673913 creator A5088525052 @default.
• W2059673913 date "2013-05-01" @default.
• W2059673913 modified "2023-10-18" @default.
• W2059673913 title "Bright dispersive waves in dual-core microstructured fiber under different laser pumps" @default.
• W2059673913 cites W2001681019 @default.
• W2059673913 cites W2084822300 @default.
• W2059673913 doi "https://doi.org/10.1109/cleoe-iqec.2013.6800837" @default.
• W2059673913 hasPublicationYear "2013" @default.
• W2059673913 type Work @default.
• W2059673913 sameAs 2059673913 @default.
• W2059673913 citedByCount "0" @default.
• W2059673913 crossrefType "proceedings-article" @default.
• W2059673913 hasAuthorship W2059673913A5004452860 @default.
• W2059673913 hasAuthorship W2059673913A5005986416 @default.
• W2059673913 hasAuthorship W2059673913A5024413079 @default.
• W2059673913 hasAuthorship W2059673913A5030271091 @default.
• W2059673913 hasAuthorship W2059673913A5035979112 @default.
• W2059673913 hasAuthorship W2059673913A5062232002 @default.
• W2059673913 hasAuthorship W2059673913A5068254460 @default.
• W2059673913 hasAuthorship W2059673913A5069698573 @default.
• W2059673913 hasAuthorship W2059673913A5078506141 @default.
• W2059673913 hasAuthorship W2059673913A5079502813 @default.
• W2059673913 hasAuthorship W2059673913A5079996430 @default.
• W2059673913 hasAuthorship W2059673913A5082449437 @default.
• W2059673913 hasAuthorship W2059673913A5088525052 @default.
• W2059673913 hasConcept C107157254 @default.
• W2059673913 hasConcept C120665830 @default.
• W2059673913 hasConcept C121332964 @default.
• W2059673913 hasConcept C132794960 @default.
• W2059673913 hasConcept C17163034 @default.
• W2059673913 hasConcept C177562468 @default.
• W2059673913 hasConcept C191154138 @default.
• W2059673913 hasConcept C192562407 @default.
• W2059673913 hasConcept C194232370 @default.
• W2059673913 hasConcept C20788544 @default.
• W2059673913 hasConcept C49040817 @default.
• W2059673913 hasConcept C520434653 @default.
• W2059673913 hasConcept C78854221 @default.
• W2059673913 hasConceptScore W2059673913C107157254 @default.
• W2059673913 hasConceptScore W2059673913C120665830 @default.
• W2059673913 hasConceptScore W2059673913C121332964 @default.
• W2059673913 hasConceptScore W2059673913C132794960 @default.
• W2059673913 hasConceptScore W2059673913C17163034 @default.
• W2059673913 hasConceptScore W2059673913C177562468 @default.
• W2059673913 hasConceptScore W2059673913C191154138 @default.
• W2059673913 hasConceptScore W2059673913C192562407 @default.
• W2059673913 hasConceptScore W2059673913C194232370 @default.
• W2059673913 hasConceptScore W2059673913C20788544 @default.
• W2059673913 hasConceptScore W2059673913C49040817 @default.
• W2059673913 hasConceptScore W2059673913C520434653 @default.
• W2059673913 hasConceptScore W2059673913C78854221 @default.
• W2059673913 hasLocation W20596739131 @default.
• W2059673913 hasLocation W20596739132 @default.
• W2059673913 hasLocation W20596739133 @default.
• W2059673913 hasLocation W20596739134 @default.
• W2059673913 hasLocation W20596739135 @default.
• W2059673913 hasOpenAccess W2059673913 @default.
• W2059673913 hasPrimaryLocation W20596739131 @default.
• W2059673913 hasRelatedWork W1910489561 @default.
• W2059673913 hasRelatedWork W2002160022 @default.
• W2059673913 hasRelatedWork W2018189772 @default.
• W2059673913 hasRelatedWork W2079387630 @default.
• W2059673913 hasRelatedWork W2099942709 @default.
• W2059673913 hasRelatedWork W2147016002 @default.
• W2059673913 hasRelatedWork W2352594185 @default.
• W2059673913 hasRelatedWork W2599890855 @default.
• W2059673913 hasRelatedWork W2767118975 @default.
• W2059673913 hasRelatedWork W2135934948 @default.
• W2059673913 isParatext "false" @default.
• W2059673913 isRetracted "false" @default.
• W2059673913 magId "2059673913" @default.
• W2059673913 workType "article" @default.