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Beautiful Chemistry Issue 2: Photoredox Catalysis in Organic Synthesis

Photoredox Catalysis

Photo catalysis is a powerful tool in organic chemical synthesis. The first synthetic application of photo catalysis was in the late 1980s. However, there was a 20-year gap before the advantages were recognized, hampered by the using of high-energy light, coupled with the disparate absorption properties of organic molecules. Over the last decade, with the discovery of absorptive organometallic complexes and organic dyes, photoredox catalysis which utilizes visible light to enable single-electron transfer between photo-excitable catalysts and organic molecules, has seen broad adoption for the activation and transformation of organic substrates, as reflected by the boosted number of publications each year.

Photocatalysis
A) Bar chart of the publications per year for the topics “Photocatalysis” (49,662 instances) and “Photoredox” (6166 instances) between 1980 and 2019, queried from the Web of Science database. B) Pie chart of “Photocatalysis” publications by research areas for the top seven categories (contains 74% of the total data set) using the same data as in A[1]

The widespread adoption and growth of visible light photoredox catalysis can, in part, be attributedto the well-established photophysical properties of photoredox catalysts. These catalysts, often polypyridyl complexes of ruthenium or iridium, can be excited by low energy visible light, with its photonic energy selectively targeting the catalysts over the organic and organometallic substrates in solution. Many transition-metal complexes and organocatalysts capable of initiating radical formation in the presence of visible light have been shown to facilitate a wide array of synthetic transformations including but not limited to cross-coupling, C-H functionalization, alkene and arene functionalization, and trifluoromethylation. 

Photoredox Catalysis
Photoredox Catalysis[2]

Carbon-Carbon Bond Formation

Over the last half century, the advent and development of palladium-catalyzed cross-coupling has revolutionized the means by which chemists synthesize new molecules. Groundbreaking work by Heck, Negishi, and Suzuki, among many others, has allowed for the construction of unprecedented molecular complexity from simple and abundant starting materials. However, despite the widespread success of palladium-catalyzed cross-couplings in the forging of bonds to sp2-hybridized carbon centers, significant limitations remain with respect to the coupling of sp3-hybridized fragments. Substantial progress toward this challenging objective has been made in the area of nickel catalysis, which, when compared to palladium, undergoes a more rapid oxidative addition into alkyl electrophiles and suffers less from deleterious β-hydride elimination with aliphatic ligands. While these developments have broadened the spectrum of strategies at the disposal of the modern chemist, the desire to expand the scope of coupling partners to simpler, cheaper, and more abundant starting materials has pushed the frontiers of catalysis. In this context, photoredox catalysis has played an integral role incorporating native functional groups in novel bond disconnections.

Decarboxylative coupling

Proposed mechanistic pathway of nickel-catalyzed photoredox- decarboxylative arylation
Proposed mechanistic pathway of nickel-catalyzed photoredox- decarboxylative arylation[3]
Carboxylic acid and alkyl halide scope in the dual nickel-catalyzed photoredox sp3-sp3coupling reaction[4]

C-H cross-coupling

Photoredox HAT and nickel-catalyzed cross-coupling
Photoredox, HAT, and nickel-catalyzed cross-coupling: proposed mechanistic pathway and catalyst combination[5]
The scope of the alkyl bromide coupling partner in the light-enabled selective sp3 C-H alkylation
The scope of the alkyl bromide coupling partner in the light-enabled selective sp3 C-H alkylation[6]

Heteroatom Arylations

Transition metal catalysis has dramatically reshaped the landscape of chemical synthesis not only in the construction of all-carbon frameworks, but in the forging of carbon-heteroatom bonds as well. Given the competence of photoredox catalysis to enable nickel to forge historically challenging carbon-carbon bonds through energy-transfer and/or electron-transfer mechanisms, similar elementary steps have been shown to enable otherwise elusive carbon−heteroatom bond formations.

C-N coupling

Metallaphotoredox-catalyzed amination amine and arene scope
Metallaphotoredox-catalyzed amination amine and arene scope[7]

C-O coupling

Alcohol and aryl halide scope in the nickel-catalyzed photoredox C-O coupling reaction[8]

Medicilon Photochemistry Platform

Medicilon has been actively developing new technologies platforms over the years, integrating emerging methods of green chemistry into its services, using currently popular photoredox chemistry, electrochemisty, catalyst screening, continuous reactions, etc., to provide our customers with high-quality economic solutions. Our photochemistry team has:

  • Rich experience in different types of photochemistry reactions;
  • Full capacity for the synthesis of variety catalysts for photocatalytic reactions;
  • Strong expertise in photoredox chemistry.

 

Equipments

References:

[1] Christopher G Thomson, et al. Heterogeneous photocatalysis in flow chemical reactors. Beilstein J Org Chem. 2020 Jun 26;16:1495-1549. doi: 10.3762/bjoc.16.125.

[2]Allison G Condie, et al. Visible-light photoredox catalysis: aza-Henry reactions via C-H functionalization. J Am Chem Soc. 2010 Feb 10;132(5):1464-5. doi: 10.1021/ja909145y.

[3] Zhiwei Zuo,et al. Dual catalysis. Merging photoredox with nickel catalysis: coupling of α-carboxyl sp³-carbons with aryl halides. Science. 2014 Jul 25;345(6195):437-40. doi: 10.1126/science.1255525. 

[4] Craig P Johnston, et al. Metallaphotoredox-catalysed sp(3)-sp(3) cross-coupling of carboxylic acids with alkyl halides. Nature. 2016 Aug 18;536(7616):322-5. doi: 10.1038/nature19056. 

[5] Megan H Shaw,et al. Native functionality in triple catalytic cross-coupling: sp³ C-H bonds as latent nucleophiles. Science. 2016 Jun 10;352(6291):1304-8. doi: 10.1126/science.aaf6635. 

[6] Chip Le,et al. Selective sp³ C-H alkylation via polarity-match-based cross-coupling. Nature. 2017 Jul 6;547(7661):79-83. doi: 10.1038/nature22813. 

[7] Emily B Corcoran, et al. Aryl amination using ligand-free Ni(II) salts and photoredox catalysis. Science. 2016 Jul 15;353(6296):279-83. doi: 10.1126/science.aag0209. 

[8] Jack A Terrett, et al. Switching on elusive organometallic mechanisms with photoredox catalysis. Nature. 2015 Aug 20;524(7565):330-4. doi: 10.1038/nature14875. 

[9] Amy Y Chan, et al. Metallaphotoredox: The Merger of Photoredox and Transition Metal Catalysis. Chem Rev. 2022 Jan 26;122(2):1485-1542. doi: 10.1021/acs.chemrev.1c00383.

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