Peter T. Cheng scite author profile

Directed C–H activation has emerged as a major approach for developing synthetically useful reactions, owing to the proximity-induced reactivity and selectivity enabled by coordinating functional groups1–6. In contrast, development of palladium-catalyzed non-directed C–H activation has faced significant challenges associated with the lack of sufficiently active palladium catalysts7–8. Current palladium catalysts are only reactive with electron-rich arenes unless an excess of arene is used9–18, which limits synthetic applications. Herein, we disclose a 2-pyridone ligand that significantly enhances the reactivity of a palladium catalyst, allowing for Pd(II)-catalyzed non-directed C–H activation of a broad range of aromatic substrates using the various arenes as the limiting reagent. The significance of this finding is demonstrated by the direct functionalization of advanced synthetic intermediates, drug molecules, and natural products that cannot be utilized in excessive quantities. The potential of this methodology to be expanded to a variety of transformations is indicated by the development of both C–H olefination and C–H carboxylation protocols. Furthermore, the site selectivity in this transformation is governed by a combination of steric and electronic effects, with the pyridone ligand enhancing the influence of sterics on the selectivity, thus providing complementary selectivity to directed C–H functionalization.

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A tautomeric ligand enables directed C‒H hydroxylation with molecular oxygen

Wang

Chekshin

et al. 2021

Science

110

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Hydroxylation of aryl carbon–hydrogen bonds with transition metal catalysts has proven challenging when oxygen is used as the oxidant. Here, we report a palladium complex bearing a bidentate pyridine/pyridone ligand that efficiently catalyzes this reaction at ring positions adjacent to carboxylic acids. Infrared, x-ray, and computational analysis support a possible role of ligand tautomerization from mono-anionic (L,X) to neutral (L,L) coordination in the catalytic cycle of aerobic carbon–hydrogen hydroxylation reaction. The conventional site selectivity dictated by heterocycles is overturned by this catalyst, thus allowing late-stage modification of compounds of pharmaceutical interest at previously inaccessible sites.

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Overcoming Limitations in Decarboxylative Arylation via Ag–Ni Electrocatalysis

et al. 2022

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A useful protocol for achieving decarboxylative cross-coupling (DCC) of redox-active esters (RAE, isolated or generated in situ) and halo(hetero)arenes is reported. This pragmatically focused study employs a unique Ag–Ni electrocatalytic platform to overcome numerous limitations that have plagued this strategically powerful transformation. In its optimized form, coupling partners can be combined in a surprisingly simple way: open to the air, using technical-grade solvents, an inexpensive ligand and Ni source, and substoichiometric AgNO3, proceeding at room temperature with a simple commercial potentiostat. Most importantly, all of the results are placed into context by benchmarking with state-of-the-art methods. Applications are presented that simplify synthesis and rapidly enable access to challenging chemical space. Finally, adaptation to multiple scale regimes, ranging from parallel milligram-based synthesis to decagram recirculating flow is presented.

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Catalytic Ring Expansions of Cyclic Alcohols Enabled by Proton-Coupled Electron Transfer

et al. 2019

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We report here a catalytic method for the modular ring expansion of cyclic aliphatic alcohols. In this work, proton-coupled electron transfer (PCET) activation of an allylic alcohol substrate affords an alkoxy radical intermediate that undergoes subsequent C-C bond cleavage to furnish an enone and a tethered alkyl radical. Recombination of this alkyl radical with the revealed olefin acceptor in turn produces a ring-expanded ketone product. The regioselectivity of this C-C bondforming event can be reliably controlled via substituents on the olefin substrate, providing a means to convert a simple N-membered ring substrate to either n+1 or n+2 ring adducts in a selective fashion.

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Ligand‐Promoted Borylation of C(sp³)H Bonds with Palladium(II) Catalysts

et al. 2015

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A quinoline-based ligand is identified to effectively promote Pd-catalyzed borylation of C(sp3)–H bonds. Primary β-C(sp3)–H bonds in carboxylic acid derivatives as well as secondary C(sp3)–H bonds in a variety of carbocyclic rings including cyclopropanes, cyclobutanes, cyclopentanes, cyclohexanes, and cycloheptanes are borylated. This directed borylation method complements existing Ir(I) and Rh(I)-catalyzed C–H borylation reactions in terms of scope and operational conditions.

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Peter T. Cheng

Ligand-accelerated non-directed C–H functionalization of arenes

A tautomeric ligand enables directed C‒H hydroxylation with molecular oxygen

Overcoming Limitations in Decarboxylative Arylation via Ag–Ni Electrocatalysis

Catalytic Ring Expansions of Cyclic Alcohols Enabled by Proton-Coupled Electron Transfer

Ligand‐Promoted Borylation of C(sp³)H Bonds with Palladium(II) Catalysts

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Peter T. Cheng

Ligand-accelerated non-directed C–H functionalization of arenes

A tautomeric ligand enables directed C‒H hydroxylation with molecular oxygen

Overcoming Limitations in Decarboxylative Arylation via Ag–Ni Electrocatalysis

Catalytic Ring Expansions of Cyclic Alcohols Enabled by Proton-Coupled Electron Transfer

Ligand‐Promoted Borylation of C(sp3)H Bonds with Palladium(II) Catalysts

Contact Info

Product

Resources

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Ligand‐Promoted Borylation of C(sp³)H Bonds with Palladium(II) Catalysts