Multifaceted catalytic hydrogenation of amides via diverse activation of a sterically confined bipyridine–ruthenium framework

Multifaceted catalytic hydrogenation of amides via diverse activation of a sterically confined bipyridine–ruthenium framework

Abstract Amides are ubiquitous and abundant in nature and our society, but are very stable and reluctant to salt-free, catalytic chemical transformations. Through the activation of a “sterically confined bipyridine–ruthenium (Ru) framework (molecularly well-designed site to confine adsorbed H2 in)”...

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Main Authors: Takashi Miura, Masayuki Naruto, Katsuaki Toda, Taiki Shimomura, Susumu Saito
Format: Article
Language:English
Published: Nature Publishing Group 2017-05-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-017-01645-z
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spelling doaj-a6c6cb4ce3f349cbb537fec468ef53b32020-12-08T00:27:48ZengNature Publishing GroupScientific Reports2045-23222017-05-017111010.1038/s41598-017-01645-zMultifaceted catalytic hydrogenation of amides via diverse activation of a sterically confined bipyridine–ruthenium frameworkTakashi Miura0Masayuki Naruto1Katsuaki Toda2Taiki Shimomura3Susumu Saito4Graduate School of Science, Nagoya UniversityGraduate School of Science, Nagoya UniversityGraduate School of Science, Nagoya UniversityGraduate School of Science, Nagoya UniversityGraduate School of Science, Nagoya UniversityAbstract Amides are ubiquitous and abundant in nature and our society, but are very stable and reluctant to salt-free, catalytic chemical transformations. Through the activation of a “sterically confined bipyridine–ruthenium (Ru) framework (molecularly well-designed site to confine adsorbed H2 in)” of a precatalyst, catalytic hydrogenation of formamides through polyamide is achieved under a wide range of reaction conditions. Both C=O bond and C–N bond cleavage of a lactam became also possible using a single precatalyst. That is, catalyst diversity is induced by activation and stepwise multiple hydrogenation of a single precatalyst when the conditions are varied. The versatile catalysts have different structures and different resting states for multifaceted amide hydrogenation, but the common structure produced upon reaction with H2, which catalyzes hydrogenation, seems to be “H–Ru–N–H.”https://doi.org/10.1038/s41598-017-01645-z
collection DOAJ
language English
format Article
sources DOAJ
author Takashi Miura
Masayuki Naruto
Katsuaki Toda
Taiki Shimomura
Susumu Saito
spellingShingle Takashi Miura
Masayuki Naruto
Katsuaki Toda
Taiki Shimomura
Susumu Saito
Multifaceted catalytic hydrogenation of amides via diverse activation of a sterically confined bipyridine–ruthenium framework
Scientific Reports
author_facet Takashi Miura
Masayuki Naruto
Katsuaki Toda
Taiki Shimomura
Susumu Saito
author_sort Takashi Miura
title Multifaceted catalytic hydrogenation of amides via diverse activation of a sterically confined bipyridine–ruthenium framework
title_short Multifaceted catalytic hydrogenation of amides via diverse activation of a sterically confined bipyridine–ruthenium framework
title_full Multifaceted catalytic hydrogenation of amides via diverse activation of a sterically confined bipyridine–ruthenium framework
title_fullStr Multifaceted catalytic hydrogenation of amides via diverse activation of a sterically confined bipyridine–ruthenium framework
title_full_unstemmed Multifaceted catalytic hydrogenation of amides via diverse activation of a sterically confined bipyridine–ruthenium framework
title_sort multifaceted catalytic hydrogenation of amides via diverse activation of a sterically confined bipyridine–ruthenium framework
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2017-05-01
description Abstract Amides are ubiquitous and abundant in nature and our society, but are very stable and reluctant to salt-free, catalytic chemical transformations. Through the activation of a “sterically confined bipyridine–ruthenium (Ru) framework (molecularly well-designed site to confine adsorbed H2 in)” of a precatalyst, catalytic hydrogenation of formamides through polyamide is achieved under a wide range of reaction conditions. Both C=O bond and C–N bond cleavage of a lactam became also possible using a single precatalyst. That is, catalyst diversity is induced by activation and stepwise multiple hydrogenation of a single precatalyst when the conditions are varied. The versatile catalysts have different structures and different resting states for multifaceted amide hydrogenation, but the common structure produced upon reaction with H2, which catalyzes hydrogenation, seems to be “H–Ru–N–H.”
url https://doi.org/10.1038/s41598-017-01645-z
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