Scientific Background on the Nobel Prize in Chemistry 2021
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O 2 ) and diarylprolinol catalyst 21. (b) The reaction proceeds by initial formation of iminium ion 23, which is attacked by hydrogen peroxide to form enamine 24 (iminium ion catalysis). Intramolecular expulsion of hydroxide ion, or its equivalent, from this species generates iminium ion 25 (enamine catalysis) which is hydrolysed to furnish epoxide 22 and regenerate catalyst 21.
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having a relatively high energy HOMO and that react with electrophiles. MacMillan and co- workers hypothesized that a one-electron oxidation of an enamine should generate the corresponding radical cation with a singly occupied molecular orbital (SOMO) that is activated toward enantioselective coupling with π-rich nucleophiles (Scheme 4). 56 For such a strategy to be successful, the enamine must undergo selective oxidation (step 2) in the presence of a secondary amine and an aldehyde, and the catalyst must induce high enantiomeric selectivity in the coupling step (step 3). This has indeed proven to be possible and this chemistry has been applied for the α-allylation, α-arylation and intramolecular cyclisation of aldehydes, furnishing the products in high yield and er. As an example, this chemistry has been applied in an efficient synthesis of the naturally occurring indolizidine alkaloid (–)-tashiromine (Scheme 5). 57 In this synthesis, the organocatalytic SOMO activation is used to construct the fused bicyclic ring system in compound 33 by allowing the cation radical, which is formed by oxidizing the enamine that is obtained from the aldehyde and catalyst 32 to add to the pyrrole moiety, and simultaneously install one new stereocentre in high er. Scheme 4. Catalytic cycle for the allylation of aldehydes using SOMO catalysis. Aldehyde 26 condenses with the organocatalyst to form enamine 27 (step 1, 27 is in equilibrium with the corresponding iminium ion, which is not shown). A one-electron oxidation of 27 furnishes cation radical 28 (step 2), which can couple with π
allyltrimethyl silane (28) to furnish intermediate 29. Fragmentation of this species will give iminium ion 30 (step 4), which is hydrolysed to the allylated aldehyde 31 and regenerates the organocatalyst (step 5).
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chemical energy is of great importance for developing a sustainable society. The inspiration for this research stems from photosynthesis, where plants use solar energy to convert a simple feedstock into chemical energy in the form of carbohydrates. One possible way to mimic this chemistry is to use transition metal catalysts (photoredox catalysts, P) to harvest light, which can then activate stable organic molecules by single-electron oxidation or reduction. This furnishes open-shell intermediates that are not readily accessible and opens the possibility to trigger otherwise difficult two-electron reaction pathways by using two one-electron transfer steps mediated by the photocatalyst. In 2008, Nicewicz and MacMillan merged this chemistry with organocatalysis, resulting in an efficient α-alkylation of aldehydes (eq. 13). 58 The role of the photocatalyst P in this reaction is to reduce the alkyl halide to an alkyl radical and a halide ion (Scheme 6, step 2). The alkyl radical then adds to an enamine, forming a carbon-carbon bond and a new alkyl radical (step 3). This species is then oxidized by the photocatalyst to yield an iminium ion (step 4), which is hydrolysed to the product and returns the organocatalyst (step 5). Two catalytic cycles are involved, one with the organocatalyst and another with the photoredox catalyst, with two points of contact. Nicewicz and MacMillan’s investigation, together with those led by Yoon 59 and Stephenson, 60
spurred considerable interest in the chemistry community, and much effort has been invested in developing photoredox-catalysed reactions. The power of this chemistry is that by using sustainable reaction conditions, it allows access to intermediates not attainable by traditional thermal activation. New chemistry has been developed, and photoredox catalysis has now been applied in most areas of organic chemistry, both in academia and industry. 61-62
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Scheme 6. Mechanism of the organocatalytic photoredox–mediated reaction in eq. 14. The photocatalyst P [Ru(bpy) 3 Cl 2 ] absorbs visible light (marked in yellow) to form the excited state Yüklə 0,93 Mb. Dostları ilə paylaş:
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