Jack A. Terrett scite author profile

Over the past 40 years, transition metal catalysis has enabled bond formation between aryl and olefinic (sp2) carbons in a selective and predictable manner with high functional group tolerance. Couplings involving alkyl (sp3) carbons have proven more challenging. Here, we demonstrate that the synergistic combination of photoredox catalysis and nickel catalysis provides an alternative cross-coupling paradigm, in which simple and readily available organic molecules can be systematically used as coupling partners. By using this photoredox-metal catalysis approach, we have achieved a direct decarboxylative sp3–sp2 cross-coupling of amino acids, as well as α-O– or phenyl-substituted carboxylic acids, with aryl halides. Moreover, this mode of catalysis can be applied to direct cross-coupling of Csp3–H in dimethylaniline with aryl halides via C–H functionalization.

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Switching on elusive organometallic mechanisms with photoredox catalysis

Terrett

Cuthbertson

Shurtleff

et al. 2015

Nature

534

387

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Transition metal-catalyzed cross-coupling reactions have become one of the most utilized carbon–carbon and carbon–heteroatom bond-forming reactions in chemical synthesis. More recently, nickel catalysis has been shown to participate in a wide variety of C–C bond forming reactions, most notably Negishi, Suzuki–Miyaura, Stille, Kumada, and Hiyama couplings1,2. Despite the tremendous advances in C–C fragment couplings, the ability to forge C–O bonds in a general fashion via nickel catalysis has been largely unsuccessful. The challenge for nickel-mediated alcohol couplings has been the mechanistic requirement for the critical C–O bond forming step (formally known as the reductive elimination step) to occur via a Ni(III) alkoxide intermediate. In this manuscript, we demonstrate that visible light-excited photoredox catalysts can modulate the preferred oxidation states of nickel alkoxides in an operative catalytic cycle, thereby providing transient access to Ni(III) species that readily participate in reductive elimination. Using this synergistic merger of photoredox and nickel catalysis, we have developed a highly efficient and general carbon–oxygen coupling reaction using abundant alcohols and aryl bromides. More significantly, we have developed a general strategy to “switch on” important yet elusive organometallic mechanisms via oxidation state modulations using only weak light and single-electron transfer (SET) catalysts.

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O–H hydrogen bonding promotes H-atom transfer from α C–H bonds for C-alkylation of alcohols

Jeffrey

Terrett

MacMillan

2015

Science

452

303

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The efficiency and selectivity of hydrogen atom transfer from organic molecules are often difficult to control in the presence of multiple potential hydrogen atom donors and acceptors. Here, we describe the mechanistic evaluation of a mode of catalytic activation that accomplishes the highly selective photoredox α-alkylation/lactonization of alcohols with methyl acrylate via a hydrogen atom transfer mechanism. Our studies indicate a particular role of tetra-n-butylammonium phosphate in enhancing the selectivity for α C–H bonds in alcohols in the presence of allylic, benzylic, α-C=O, and α-ether C–H bonds.

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Native functionality in triple catalytic cross-coupling: sp ³ C–H bonds as latent nucleophiles

Shaw

Shurtleff

Terrett

et al. 2016

Science

537

289

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The use of sp3 C–H bonds—which are ubiquitous in organic molecules—as latent nucleophile equivalents for transition metal–catalyzed cross-coupling reactions has the potential to substantially streamline synthetic efforts in organic chemistry while bypassing substrate activation steps. Through the combination of photoredox-mediated hydrogen atom transfer (HAT) and nickel catalysis, we have developed a highly selective and general C–H arylation protocol that activates a wide array of C–H bonds as native functional handles for cross-coupling. This mild approach takes advantage of a tunable HAT catalyst that exhibits predictable reactivity patterns based on enthalpic and bond polarity considerations to selectively functionalize a-amino and a-oxy sp3 C–H bonds in both cyclic and acyclic systems.

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Direct β-Alkylation of Aldehydes via Photoredox Organocatalysis

2014

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Direct β-alkylation of saturated aldehydes has been accomplished by synergistically combining photoredox catalysis and organocatalysis. Photon-induced enamine oxidation provides an activated β-enaminyl radical intermediate, which readily combines with a wide range of Michael acceptors to produce β-alkyl aldehydes in a highly efficient manner. Furthermore, this redox-neutral, atom-economical C–H functionalization protocol can be achieved both inter- and intramolecularly. Mechanistic studies by various spectroscopic methods suggest that a reductive quenching pathway is operable.

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Jack A. Terrett

Merging photoredox with nickel catalysis: Coupling of α-carboxyl sp ³ -carbons with aryl halides

Switching on elusive organometallic mechanisms with photoredox catalysis

O–H hydrogen bonding promotes H-atom transfer from α C–H bonds for C-alkylation of alcohols

Native functionality in triple catalytic cross-coupling: sp ³ C–H bonds as latent nucleophiles

Direct β-Alkylation of Aldehydes via Photoredox Organocatalysis

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About

Jack A. Terrett

Merging photoredox with nickel catalysis: Coupling of α-carboxyl sp 3 -carbons with aryl halides

Switching on elusive organometallic mechanisms with photoredox catalysis

O–H hydrogen bonding promotes H-atom transfer from α C–H bonds for C-alkylation of alcohols

Native functionality in triple catalytic cross-coupling: sp 3 C–H bonds as latent nucleophiles

Direct β-Alkylation of Aldehydes via Photoredox Organocatalysis

Contact Info

Product

Resources

About

Merging photoredox with nickel catalysis: Coupling of α-carboxyl sp ³ -carbons with aryl halides

Native functionality in triple catalytic cross-coupling: sp ³ C–H bonds as latent nucleophiles