Terunori Fujita spends much of his time researching Polymer chemistry, Catalysis, Polymerization, Imine and Organic chemistry. His research integrates issues of Titanium, Polyethylene and Ethylene in his study of Polymer chemistry. His Ethylene research is multidisciplinary, incorporating elements of Norbornene and Monomer.
As a part of the same scientific study, he usually deals with the Catalysis, concentrating on Copolymer and frequently concerns with Olefin fiber. His study on Metallocene is often connected to Living polymerization and Chain-growth polymerization as part of broader study in Polymerization. His Imine study incorporates themes from Chelation and Molar mass distribution.
His primary areas of study are Polymer chemistry, Catalysis, Polymerization, Organic chemistry and Copolymer. His Polymer chemistry research integrates issues from Imine, Olefin fiber, Polymer, Transition metal and Ethylene. His studies deal with areas such as Metallocene, Methylaluminoxane and Zirconium as well as Ethylene.
His research integrates issues of Tacticity, Chelation, Polyethylene, Hydrocarbon and Post-metallocene catalyst in his study of Catalysis. His work in the fields of Polymerization, such as Coordination polymerization and Olefin polymerization, intersects with other areas such as Living polymerization and Chain-growth polymerization. His work deals with themes such as Dispersity, Intrinsic viscosity and Monomer, which intersect with Copolymer.
Terunori Fujita mainly focuses on Catalysis, Polymer chemistry, Organic chemistry, Polymerization and Olefin fiber. He interconnects Yield and Post-metallocene catalyst in the investigation of issues within Catalysis. The concepts of his Polymer chemistry study are interwoven with issues in Copolymer, Polymer, Imine, Transition metal and Ethylene.
His studies in Copolymer integrate themes in fields like Tacticity and Monomer. Terunori Fujita undertakes multidisciplinary studies into Polymerization and Living polymerization in his work. His Olefin fiber research includes elements of Polyethylene and Halogen.
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FI catalysts for olefin polymerization--a comprehensive treatment.
Haruyuki Makio;Hiroshi Terao;Akihiko Iwashita;Terunori Fujita.
Chemical Reviews (2011)
A Family of Zirconium Complexes Having Two Phenoxy−Imine Chelate Ligands for Olefin Polymerization
Shigekazu Matsui;Makoto Mitani;Junji Saito;Yasushi Tohi.
Journal of the American Chemical Society (2001)
Living Polymerization of Ethylene Catalyzed by Titanium Complexes Having Fluorine-Containing Phenoxy−Imine Chelate Ligands
Makoto Mitani;Jun-ichi Mohri;Yasunori Yoshida;Junji Saito.
Journal of the American Chemical Society (2002)
FI Catalysts: A New Family of High Performance Catalysts for Olefin Polymerization
Haruyuki Makio;Norio Kashiwa;Terunori Fujita.
Advanced Synthesis & Catalysis (2002)
Syndiospecific living propylene polymerization catalyzed by titanium complexes having fluorine-containing phenoxy-imine chelate ligands.
Makoto Mitani;Rieko Furuyama;Jun-ichi Mohri;Junji Saito.
Journal of the American Chemical Society (2003)
Living Polymerization of Ethylene with a Titanium Complex Containing Two Phenoxy-Imine Chelate Ligands.
Junji Saito;Makoto Mitani;Jun-ichi Mohri;Yasunori Yoshida.
Angewandte Chemie (2001)
Olefin polymerization catalysts, transition metal compounds, processes for olefin polymerization, and .alpha.-olefin/conjugated diene copolymers
Fujita Terunori;Tohi Yasushi;Mitani Makoto;Matsui Shigekazu.
High-performance olefin polymerization catalysts discovered on the basis of a new catalyst design concept
Tomoaki Matsugi;Terunori Fujita.
Chemical Society Reviews (2008)
FI Catalysts: super active new ethylene polymerization catalysts
Shigekazu Matsui;Terunori Fujita.
Catalysis Today (2001)
Living Copolymerization of Ethylene with Norbornene Catalyzed by Bis(Pyrrolide−Imine) Titanium Complexes with MAO
Yasunori Yoshida;† Jun-ichi Mohri;† Sei-ichi Ishii;Makoto Mitani.
Journal of the American Chemical Society (2004)
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