Organic chemistry is closely attributed to Redox in his research. His research on Molecule often connects related topics like Rotaxane. He combines Polymer chemistry and Polymerization in his studies. In his works, he conducts interdisciplinary research on Polymerization and Monomer. By researching both Monomer and Polymer chemistry, he produces research that crosses academic boundaries. He performs integrative study on Polymer and Adamantane. His research is interdisciplinary, bridging the disciplines of Biochemistry and Cyclodextrin. His Biochemistry study frequently links to other fields, such as Cyclodextrin. He incorporates Nanotechnology and Self-assembly in his research.
Polymerization and Monomer are the subject areas of his Polymer study. His Dimer research extends to Organic chemistry, which is thematically connected. His study brings together the fields of Self-healing hydrogels and Polymer chemistry. He incorporates Molecule and Nanotechnology in his studies. Yoshinori Takashima merges Nanotechnology with Supramolecular chemistry in his study. Yoshinori Takashima integrates Cyclodextrin with Supramolecular chemistry in his study. Yoshinori Takashima performs integrative study on Catalysis and Organic chemistry in his works. In his articles, Yoshinori Takashima combines various disciplines, including Composite material and Polymer. He integrates several fields in his works, including Stereochemistry and Molecule.
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Redox-responsive self-healing materials formed from host–guest polymers
Masaki Nakahata;Yoshinori Takashima;Hiroyasu Yamaguchi;Akira Harada.
Nature Communications (2011)
Cyclodextrin-based supramolecular polymers
Akira Harada;Yoshinori Takashima;Hiroyasu Yamaguchi.
Chemical Society Reviews (2009)
Supramolecular polymeric materials via cyclodextrin-guest interactions.
Akira Harada;Yoshinori Takashima;Masaki Nakahata.
Accounts of Chemical Research (2014)
Macroscopic self-assembly through molecular recognition
Akira Harada;Ryosuke Kobayashi;Yoshinori Takashima;Akihito Hashidzume.
Nature Chemistry (2011)
Expansion-contraction of photoresponsive artificial muscle regulated by host-guest interactions
Yoshinori Takashima;Shogo Hatanaka;Miyuki Otsubo;Masaki Nakahata.
Nature Communications (2012)
Preorganized hydrogel: self-healing properties of supramolecular hydrogels formed by polymerization of host-guest-monomers that contain cyclodextrins and hydrophobic guest groups
Takahiro Kakuta;Yoshinori Takashima;Masaki Nakahata;Miyuki Otsubo.
Advanced Materials (2013)
Photoswitchable gel assembly based on molecular recognition
Hiroyasu Yamaguchi;Yuichiro Kobayashi;Ryosuke Kobayashi;Yoshinori Takashima.
Nature Communications (2012)
Photoswitchable supramolecular hydrogels formed by cyclodextrins and azobenzene polymers.
Shingo Tamesue;Yoshinori Takashima;Hiroyasu Yamaguchi;Seiji Shinkai.
Angewandte Chemie (2010)
Self-Healing, Expansion–Contraction, and Shape-Memory Properties of a Preorganized Supramolecular Hydrogel through Host–Guest Interactions†
Kohei Miyamae;Masaki Nakahata;Yoshinori Takashima;Akira Harada.
Angewandte Chemie (2015)
Fast response dry-type artificial molecular muscles with [c2]daisy chains
Kazuhisa Iwaso;Yoshinori Takashima;Akira Harada.
Nature Chemistry (2016)
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