Kondoh Azusa

コンドウアズサ | Kondoh Azusa

Affiliation and department：
Homepage URL (2)： http://www.orgreact.sakura.ne.jp/members/kondoindex.html , http://www.orgreact.sakura.ne.jp/members/en-kondoindex.html

Research field (1)： Synthetic organic chemistry

Research keywords (3)：有機分子触媒 , 有機金属化学 , 有機合成化学

Research theme for competitive and other funds (7)：

2022 - 2027 Development of advanced molecular transformations based on innovative molecular design of higher order organosuperbase catalysts enabling molecular recognition
2022 - 2025 Development of advanced molecular transformations based on innovative molecular design of higher order organosuperbase catalysts enabling molecular recognition
2016 - 2021 Development of Functional Organosuperbase Catalysts Enabling Molecular Recognition
2016 - 2019 Development of New Method for Synthesis of Heterocyclic Compounds Utilizing Cycloaddition Reactions Catalyzed by Bronsted Base
2016 - 2017 基質認識型・超強塩基性有機分子触媒の創製

Show all

Papers (82)：

Azusa Kondoh, Sena Takada, Kohei Aita, Masahiro Terada. Formal Addition of β-Acylalkenyl Anions to Ketones Utilizing [1,2]-Phospha-Brook Rearrangement under Brønsted Base Catalysis. European Journal of Organic Chemistry. 2023
Azusa Kondoh, Kohei Aita, Masahiro Terada. Synthesis of Polysubstituted Naphthofurans and Indenofurans Based on a Regiodivergent Intramolecular Carbometalation Strategy with 2-(2’-Alkynylaryl)-3-iodofurans. Chemistry - A European Journal. 2023
Azusa Kondoh, Masahiro Terada. [1,2]-Phospha-Brook Rearrangement as Tool for Generation of Anionic Nucleophiles in Addition Reactions under Brønsted Base Catalysis. Asian Journal of Organic Chemistry. 2023
Saikat Das, Azusa Kondoh, Masahiro Terada. Enantioselective direct Michael addition of cyanohydrin ether derivatives to enones catalyzed by chiral bis(guanidino)iminophosphorane organosuperbase. Chemical Science. 2023
Azusa Kondoh, Masahiro Terada. Synthesis of 2,2-Disubstituted 2 H -Chromenes through Carbon-Carbon Bond Formation Utilizing a [1,2]-Phospha-Brook Rearrangement under Brønsted Base Catalysis. Chemistry - A European Journal. 2022

ｍore...

MISC (9)：

Azusa Kondoh, Masahiro Terada. Chiral Organosuperbase Catalysts as Useful Tools for Developing Enantioselective Reactions. ALDRICHIMICA ACTA. 2022. 55. 1. 9-15
Azusa Kondoh, Masahiro Terada. Development of molecular transformations on the basis of catalytic generation of anionic species by organosuperbase. Bulletin of the Chemical Society of Japan. 2021. 94. 1. 339-356
近藤梓, 菊池隼, 寺田眞浩. 基質認識型有機酸・塩基触媒の設計開発. 触媒年鑑触媒技術の動向と展望 2019. 2019. 24
近藤梓, 寺田眞浩. 有機分子触媒有機超強塩基触媒が拓く新たな炭素-炭素結合生成反応. Chemical Times. 2018. 2018. 2. 8-13
近藤梓, 寺田眞浩. Novel Transformations Utilizing [1,2]-Phospha-Brook Rearrangement Under Bronsted Base Catalysis. 有機合成化学協会誌. 2018. 76. 2. 151-163-163

ｍore...

Books (3)：

Asymmetric Organocatalysis: New Strategies, Catalysts, and Opportunities, 2 Volumes
Wiley-VCH 2022 ISBN:9783527349074
Catalytic asymmetric synthesis
John Wiley & Sons 2022 ISBN:9781119736394
Atropisomerism and axial chirality
World Scientific 2019 ISBN:9781786346452

Education (2)：

2005 - 2010 京都大学大学院工学研究科材料化学専攻
2001 - 2005 Kyoto University Faculty of Engineering School of Industrial Chemistry

Professional career (1)：

Work history (3)：

2014/06 - 2020/03 Tohoku University Research and Analytical Center for Giant Molecules, Graduate School of Science
2012/04 - 2014/05 東北大学
2010/04 - 2012/03 マックスプランク石炭研究所博士研究員

Awards (9)：

2022/07 - 2022 Asian Core Program Lectureship Award (South Korea & Taiwan) Chiral Ureates as Chiral Strong Brønsted Base Catalysts
2022/06 - 公益社団法人新化学技術推進協会第21回グリーン・サステイナブルケミストリー(GSC)賞奨励賞不斉有機超強塩基触媒を用いた不斉分子変換反応の開発
2020/12 - Thieme Chemistry Thieme Journals Award 2021
2020/10 - 公益財団法人MSD生命科学財団 Chemist Award BCA 2020 有機超強塩基によるアニオンの触媒的発生を鍵とする分子変換反応の開発
2020/05 - 東北大学東北大学ディスティングイッシュトリサーチャー

Show all

Association Membership(s) (4)：

アメリカ化学会 , THE SOCIETY OF SYNTHETIC ORGANIC CHEMISTRY, JAPAN , THE CHEMICAL SOCIETY OF JAPAN , The Kinka Chemical Society, Japan

※ Researcher’s information displayed in J-GLOBAL is based on the information registered in researchmap. For details, see here.

Return to Previous Page