His primary areas of study are Photochemistry, Cationic polymerization, Polymerization, Photopolymer and Radical polymerization. His study on Photodissociation is often connected to Flash photolysis as part of broader study in Photochemistry. His research on Cationic polymerization concerns the broader Polymer chemistry.
His Polymerization study incorporates themes from Laser imaging, Catalysis and Dispersity. The concepts of his Photopolymer study are interwoven with issues in Ring-opening polymerization, Photoredox catalysis, Light intensity, Radical and Halogen lamp. In Radical polymerization, Frédéric Dumur works on issues like Halide, which are connected to Methacrylate.
His main research concerns Photochemistry, Polymerization, Photopolymer, Cationic polymerization and Radical polymerization. His work on Photodissociation as part of general Photochemistry research is frequently linked to Flash photolysis, thereby connecting diverse disciplines of science. His Polymerization research is multidisciplinary, relying on both Light intensity, Photoredox catalysis and Monomer.
His Photopolymer research focuses on subjects like Cyclic voltammetry, which are linked to Luminescence, Electroluminescence, Fluorescence spectroscopy and Phosphorescence. His research in Cationic polymerization intersects with topics in Carbazole, Spin trapping, Radical, Benzophenone and Halogen lamp. His research investigates the connection between Radical polymerization and topics such as Redox that intersect with issues in Reducing agent and Oxidizing agent.
Frédéric Dumur mainly focuses on Photopolymer, Photochemistry, Polymerization, Radical polymerization and Cationic polymerization. His biological study spans a wide range of topics, including Nanotechnology, Light-emitting diode, Photoinitiator, Ketone and Radical. His Photochemistry study combines topics from a wide range of disciplines, such as Fourier transform infrared spectroscopy, Electron donor and Photothermal therapy.
His Polymerization research incorporates themes from Light intensity, Acrylate, Monomer and Visible spectrum. His Radical polymerization research incorporates elements of Tertiary amine, Chalcone, Photodissociation, Cyclic voltammetry and Amine gas treating. His Cationic polymerization study deals with the bigger picture of Polymer chemistry.
His scientific interests lie mostly in Photopolymer, Photochemistry, Polymerization, Radical polymerization and Photoinitiator. His Photopolymer research is multidisciplinary, incorporating perspectives in Combinatorial chemistry, Cationic polymerization, Acrylate and Reaction mechanism. Frédéric Dumur works in the field of Photochemistry, focusing on Carbazole in particular.
The Polymerization study combines topics in areas such as Light intensity, Fourier transform infrared spectroscopy, Visible spectrum and Monomer. His research integrates issues of Photosensitivity and Chalcone in his study of Radical polymerization. His studies examine the connections between Photoinitiator and genetics, as well as such issues in Electron transfer, with regards to Photothermal therapy and Methacrylate.
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A reversible, unidirectional molecular rotary motor driven by chemical energy.
Stephen P. Fletcher;Frédéric Dumur;Michael M. Pollard;Ben L. Feringa.
Visible light sensitive photoinitiating systems: Recent progress in cationic and radical photopolymerization reactions under soft conditions
Pu Xiao;Jing Zhang;Frédéric Dumur;Mohamad Ali Tehfe.
Progress in Polymer Science (2015)
Polyaromatic Structures as Organo-Photoinitiator Catalysts for Efficient Visible Light Induced Dual Radical/Cationic Photopolymerization and Interpenetrated Polymer Networks Synthesis
Mohamad-Ali Tehfe;Jacques Lalevée;Sofia Telitel;Emmanuel Contal.
Subtle ligand effects in oxidative photocatalysis with iridium complexes: application to photopolymerization.
Jacques Lalevée;Mathieu Peter;Frédéric Dumur;Didier Gigmes.
Chemistry: A European Journal (2011)
Recent advances in organic light-emitting devices comprising copper complexes: A realistic approach for low-cost and highly emissive devices?
Organic Electronics (2015)
Novel fused D-A dyad and A-D-A triad incorporating tetrathiafulvalene and p-benzoquinone.
Frédéric Dumur;Nicolas Gautier;Nuria Gallego-Planas;Yücel Sahin.
Journal of Organic Chemistry (2004)
Structure Design of Naphthalimide Derivatives: Toward Versatile Photoinitiators for Near-UV/Visible LEDs, 3D Printing, and Water-Soluble Photoinitiating Systems
Jing Zhang;Frédéric Dumur;Pu Xiao;Bernadette Graff.
Intramolecular Electron Transfer Mediated by a Tetrathiafulvalene Bridge in a Purely Organic Mixed‐Valence System
Nicolas Gautier;Frédéric Dumur;Vega Lloveras;José Vidal-Gancedo.
Angewandte Chemie (2003)
Iridium Photocatalysts in Free Radical Photopolymerization under Visible Lights
Jacques Lalevée;Mohamad-Ali Tehfe;Frédéric Dumur;Didier Gigmes.
ACS Macro Letters (2012)
Recent advances on organic blue thermally activated delayed fluorescence (TADF) emitters for organic light-emitting diodes (OLEDs)
Thanh Tuân Bui;Fabrice Goubard;Malika Ibrahim-Ouali;Didier Gigmes.
Beilstein Journal of Organic Chemistry (2018)
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