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From C-H to C-C at Room Temperature 게시판 상세보기
Title From C-H to C-C at Room Temperature
Embargo date 2017-12-27 12:00 Hits 359
Research Center Center for Catalytic Hydrocarbon Functionalizations
Press release  
att.  

From C-H to C-C at Room Temperature

- By oxidizing the iridium center of the reaction intermediate,
IBS scientists achieve arylation of C-H bonds at mild conditions -

Carbon-carbon (C-C) bonds make up the skeleton of all organic molecules. However, creating such ubiquitous C-C bonds artificially is still a complicated task. In particular, since several molecules used in medicine, pharmacology and material chemistry contain aryl groups, devising a way to efficiently and selectively introduce this chemical group is a major goal for organic chemists. Currently, most arylation reactions require harsh reaction conditions, including high temperatures and excess additives.

Scientists at the Center for Catalytic Hydrocarbon Functionalization, within the Institute for Basic Science (IBS, South Korea), devised a method to selectively introduce aryl groups into C-H bonds at room temperature. Published in Nature Chemistry, the study also clarifies the details of this reaction, which turned out to be different from the conventional idea.

In simple terms, the procedure consists of three main steps. Firstly, the iridium catalyst activates the C-H containing substrate. Secondly, the arylsilane attacks the metal, creating an intermediate molecule. The team crystallized such intermediate and demonstrated that oxidizing the iridium center of the intermediate (third step) is beneficial to achieve a low energy arylation reaction.

The proposed reaction mechanism was verified with electroparamagnetic resonance, cyclic voltametry and computer simulations. “Developing more efficient and environmetally benign oxidation system is our next goal,” concludes Kwangmin Shin, first author of the study.


Figure 1Oxidation of the metal (M, iridium, blue pathway) leads to a 19 kcal/mol decrease in reaction’s energy barrier, and allows the arylation to occur at room temperature.


Figure 2Arylation mechanism proposed by IBS researchers. The reaction proceeds through a novel pathway in which the reductive elimination takes place more easily after the intermediate is selectively oxidized.


Figure 3IBS scientists were able to isolate and crystallize the reaction intermediate

Letizia Diamante

Notes for editors

- References
Kwangmin Shin, Yoonsu Park, Mu-Hyun Baik and Sukbok Chang. Iridium-catalysed arylation of C–H bonds enabled by oxidatively induced reductive elimination. Nature Chemistry (2017). DOI: 10.1038/nchem.2900.

- Media Contact
For further information or to request media assistance, please contact: Mr. Shi Bo Shim, Head of Department of Communications, Institute for Basic Science (+82-42-878-8189, sibo@ibs.re.kr); Mr. Jung Gyu Kim, Global Officer, Department of Communications, Institute for Basic Science (+82-42-878-8172, jungkki1@ibs.re.kr); or Dr. Letizia Diamante, Science Writer and Visual Producer (+82-42-878-8260, letizia@ibs.re.kr).

- About the Institute for Basic Science (IBS)
IBS was founded in 2011 by the government of the Republic of Korea with the sole purpose of driving forward the development of basic science in South Korea. IBS has launched 28 research centers as of January 2017. There are nine physics, one mathematics, six chemistry, eight life science, one earth science and three interdisciplinary research centers.

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