Alexandre Kudlinski mainly focuses on Optics, Optical fiber, Photonic-crystal fiber, Supercontinuum and Optoelectronics. The Optics study combines topics in areas such as Computer simulation and Instability. His Optical fiber research integrates issues from Second-harmonic generation, Fiber, Raman spectroscopy, Refractive index and Nonlinear system.
His Photonic-crystal fiber study combines topics from a wide range of disciplines, such as Infrared and Biomedical engineering. His work deals with themes such as Bandwidth, Fiber laser, Visible spectrum and Nonlinear optics, which intersect with Supercontinuum. The study incorporates disciplines such as Four-wave mixing and Zero-dispersion wavelength in addition to Wavelength.
Alexandre Kudlinski focuses on Optics, Optical fiber, Photonic-crystal fiber, Optoelectronics and Dispersion. His Optics study incorporates themes from Fiber and Modulation. His Optical fiber research includes themes of Soliton, Soliton, Nonlinear system and Raman scattering.
Many of his studies on Photonic-crystal fiber apply to Amplifier as well. The various areas that he examines in his Optoelectronics study include Ultrashort pulse, Optical pumping, Microstructured optical fiber and Optical amplifier. Alexandre Kudlinski has included themes like Wavelength, Zero-dispersion wavelength, Four-wave mixing, Resonator and Modulational instability in his Dispersion study.
His primary areas of investigation include Optics, Optical fiber, Dispersion, Modulation and Nonlinear system. As part of his studies on Optics, Alexandre Kudlinski frequently links adjacent subjects like Parametric instability. He has researched Optical fiber in several fields, including Fermi Gamma-ray Space Telescope, Phase, Heterodyne and Optical amplifier.
His Dispersion research incorporates elements of Wavelength, Optoelectronics, Resonator, Pulse and Mechanics. In his work, Total internal reflection is strongly intertwined with Fiber, which is a subfield of Optoelectronics. Alexandre Kudlinski has included themes like Core and Nonlinear optics in his Modulation study.
His primary scientific interests are in Optics, Optical fiber, Phase, Dispersion and Modulation. Specifically, his work in Optics is concerned with the study of Raman scattering. His studies in Optical fiber integrate themes in fields like Amplitude, Mechanics, Computer simulation and Optical amplifier.
His Phase research focuses on Symmetry breaking and how it connects with Mixing and Wave turbulence. His biological study spans a wide range of topics, including Computational physics, Resonator and Frequency comb. His studies deal with areas such as Multi-mode optical fiber, Core, Nonlinear optics and Complex dynamics as well as Modulation.
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Zero-dispersion wavelength decreasing photonic crystal fibers for ultraviolet-extended supercontinuum generation
A Kudlinski;A K George;J C Knight;J C Travers.
Optics Express (2006)
Roadmap on optical rogue waves and extreme events
Nail Akhmediev;Bertrand Kibler;Fabio Baronio;Milivoj Belic.
Journal of Optics (2016)
Real-time full bandwidth measurement of spectral noise in supercontinuum generation.
Benjamin Wetzel;Alessio Stefani;Laurent Larger;Pierre-Ambroise Lacourt.
Scientific Reports (2012)
Observation of extreme temporal events in CW-pumped supercontinuum
A Mussot;A Kudlinski;M Kolobov;E Louvergneaux.
Optics Express (2009)
Third-order dispersion for generating optical rogue solitons
M. Taki;A. Mussot;A. Kudlinski;E. Louvergneaux.
Physics Letters A (2010)
Development of a real-time flexible multiphoton microendoscope for label-free imaging in a live animal
Guillaume Ducourthial;Pierre Leclerc;Tigran Mansuryan;Marc Fabert.
Scientific Reports (2015)
Real time noise and wavelength correlations in octave-spanning supercontinuum generation
Thomas Godin;Benjamin Wetzel;Thibaut Sylvestre;Laurent Larger.
Optics Express (2013)
Fibre multi-wave mixing combs reveal the broken symmetry of Fermi-Pasta-Ulam recurrence
Arnaud Mussot;Corentin Naveau;Matteo Conforti;Alexandre Kudlinski.
Nature Photonics (2018)
High-resolution multimodal flexible coherent Raman endoscope.
Alberto Lombardini;Vasyl Mytskaniuk;Siddharth Sivankutty;Esben Ravn Andresen;Esben Ravn Andresen.
Light-Science & Applications (2018)
Second-harmonic generation of thermally poled chalcogenide glass.
M Guignard;V Nazabal;J Troles;F Smektala.
Optics Express (2005)
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