M
Maxime Cavillon
Researcher at Université Paris-Saclay
Publications - 57
Citations - 641
Maxime Cavillon is an academic researcher from Université Paris-Saclay. The author has contributed to research in topics: Optical fiber & Laser. The author has an hindex of 11, co-authored 43 publications receiving 401 citations. Previous affiliations of Maxime Cavillon include University of Illinois at Urbana–Champaign & University of Paris-Sud.
Papers
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Journal ArticleDOI
Materials for optical fiber lasers: A review
TL;DR: The relevance of the material in high power fiber laser technologies is reviewed, and where appropriate, materials-based paths to the enhancement of laser performance will be underscored.
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Additivity of the coefficient of thermal expansion in silicate optical fibers.
TL;DR: A model that predicts the material additivity of the thermal expansion coefficient in the binary silicates glasses most commonly used for present and emerging and emerging optical fibers and gives direct insight on the parameters that govern its additivity in silicate glasses is proposed.
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A Unified Materials Approach to Mitigating Optical Nonlinearities in Optical Fiber. II. B. The Optical Fiber, Material Additivity and the Nonlinear Coefficients
TL;DR: In this paper, the authors describe the continuum models employed to deduce the effects of differential thermal expansion in the optical fiber in addition to the nonlinear optical behaviors at high intensities of light.
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A unified materials approach to mitigating optical nonlinearities in optical fiber. III. Canonical examples and materials road map
TL;DR: Ballato et al. as discussed by the authors provide a road map for the development of simple core/clad optical fibers whose enhanced performance is achieved materially and not through the more conventional present routes of geometrically complex fiber design.
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Less than 1% quantum defect fiber lasers via ytterbium-doped multicomponent fluorosilicate optical fiber.
TL;DR: Two ytterbium-doped fiber lasers exhibiting quantum defects of less than 1% are demonstrated, in which pumping at wavelengths of 976.6 and 981.0 nm yielded lasing at wavelength of 985.7 and 989.8 nm, respectively.