2018 - OSA Fellows Maksim Skorobogatiy École Polytechnique de Montréal, Canada For pioneering contributions to the development of microstructured and photonic-crystal multimaterial fibers and their application to light delivery, sensing, smart textiles and arts.
His primary scientific interests are in Optics, Photonic-crystal fiber, Optical fiber, Optoelectronics and Photonic crystal. Maksim Skorobogatiy combines topics linked to Fiber with his work on Optics. His study in Photonic-crystal fiber is interdisciplinary in nature, drawing from both Fiber Bragg grating, Surface plasmon, Plastic-clad silica fiber, Graded-index fiber and Cladding.
His Optoelectronics study combines topics in areas such as Radiation mode and Detector. His Photonic crystal research incorporates elements of Theoretical physics, Asymptotic analysis, Applied physics, Nonlinear system and Group theory. His Terahertz radiation research is multidisciplinary, incorporating elements of Transmission, Refractive index, Electromagnetic spectrum, Bending and Total internal reflection.
Optics, Optoelectronics, Terahertz radiation, Photonic-crystal fiber and Optical fiber are his primary areas of study. His Optics study frequently draws connections to adjacent fields such as Fiber. In his research on the topic of Optoelectronics, Polymer is strongly related with Core.
In his work, Modal is strongly intertwined with Cladding, which is a subfield of Terahertz radiation. His Photonic-crystal fiber research focuses on Graded-index fiber and how it relates to Dispersion-shifted fiber. The Optical fiber study combines topics in areas such as Total internal reflection and Power dividers and directional couplers.
Terahertz radiation, Optics, Optoelectronics, Detector and Wireless are his primary areas of study. His biological study spans a wide range of topics, including Photonics, Transmission, Refractive index, Bit error rate and Communications system. His study looks at the relationship between Refractive index and fields such as Porosity, as well as how they intersect with chemical problems.
His work deals with themes such as Phase and k-space, which intersect with Optics. His work in Optoelectronics tackles topics such as Fiber which are related to areas like Ion. The various areas that Maksim Skorobogatiy examines in his Waveguide study include Reflector, Band gap and Photonic crystal.
His main research concerns Terahertz radiation, Optics, Optoelectronics, Composite material and Diffraction. He interconnects Waveguide, Detector, Transmission, Optical fiber and Sapphire in the investigation of issues within Terahertz radiation. His research ties Porosity and Optics together.
His research integrates issues of Nanotechnology, Separator, Lithium-ion battery, Current collector and Conductivity in his study of Optoelectronics. His study in the field of Piezoelectricity is also linked to topics like Tin. His research investigates the connection between Continuous wave and topics such as Surface wave that intersect with problems in Photonic crystal.
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Perturbation theory for Maxwell's equations with shifting material boundaries
Steven G. Johnson;M. Ibanescu;M. A. Skorobogatiy;O. Weisberg.
Physical Review E (2002)
Nanotechnology in Textiles
Ali K. Yetisen;Hang Qu;Amir Manbachi;Amir Manbachi;Haider Butt.
ACS Nano (2016)
Low-loss asymptotically single-mode propagation in large-core OmniGuide fibers.
Steven G. Johnson;Mihai Ibanescu;M. Skorobogatiy;Ori Weisberg.
Optics Express (2001)
Porous polymer fibers for low-loss Terahertz guiding.
Alireza Hassani;Alexandre Dupuis;Maksim Skorobogatiy.
Optics Express (2008)
Design of the Microstructured Optical Fiber-based Surface Plasmon Resonance sensors with enhanced microfluidics
A Hassani;M Skorobogatiy.
Optics Express (2006)
Adiabatic theorem and continuous coupled-mode theory for efficient taper transitions in photonic crystals.
Steven G. Johnson;Peter Bienstman;M. A. Skorobogatiy;Mihai Ibanescu.
Physical Review E (2002)
Suspended core subwavelength fibers: towards practical designs for low-loss terahertz guidance
Mathieu Rozé;Bora Ung;Anna Mazhorova;Markus Walther.
Optics Express (2011)
Fundamentals of Photonic Crystal Guiding
Maksim Skorobogatiy;Jianke Yang.
Photonic bandgap fiber-based Surface Plasmon Resonance sensors.
Bertrand Gauvreau;Alireza Hassani;Majid Fassi Fehri;Andrei Kabashin.
Optics Express (2007)
Design criteria for microstructured-optical-fiber-based surface-plasmon-resonance sensors
Alireza Hassani;Maksim Skorobogatiy.
Journal of The Optical Society of America B-optical Physics (2007)
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