Nature inspired singlet oxygen generation to access α-amino carbonyl compounds 1,2-acyl migration

We have discovered chlorophyll catalyzed 1,2-acyl migration reactions to achieve α-amino carbonyl compounds directly from the enaminones. In general, singlet oxygen is generated during photosynthesis in the photosystem II center. This singlet oxygen can readily react with the unsaturated double bond...

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Veröffentlicht in:	Green chemistry : an international journal and green chemistry resource : GC 2021-01, Vol.23 (1), p.379-387
Hauptverfasser:	Schilling, Waldemar, Zhang, Yu, Sahoo, Prakash Kumar, Sarkar, Samir Kumar, Gandhi, Sivaraman, Roesky, Herbert W, Das, Shoubhik
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creator	Schilling, Waldemar Zhang, Yu Sahoo, Prakash Kumar Sarkar, Samir Kumar Gandhi, Sivaraman Roesky, Herbert W Das, Shoubhik
description	We have discovered chlorophyll catalyzed 1,2-acyl migration reactions to achieve α-amino carbonyl compounds directly from the enaminones. In general, singlet oxygen is generated during photosynthesis in the photosystem II center. This singlet oxygen can readily react with the unsaturated double bonds present in biomolecules. This reactivity intrigued us to apply this concept towards unsaturated enaminones and others to achieve highly valuable compounds. Indeed, this photosensitizer is very cheap, commercially available, main group metal based and provided excellent efficiency for singlet oxygen mediated chemistry by achieving high turnover number (TON) > 300 with a high turnover frequency (TOF) of 50 h −1 . Finally, a combination of DFT calculations and detailed mechanistic experiments provided the exact role of the photosensitizer and clear insights into the reaction. We have discovered chlorophyll catalyzed 1,2-acyl migration reactions to achieve α-amino carbonyl compounds directly from the enaminones.
doi_str_mv	10.1039/d0gc03555f
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title	Nature inspired singlet oxygen generation to access α-amino carbonyl compounds 1,2-acyl migration
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