Proton-coupled electron transfer: the mechanistic underpinning for radical transport and catalysis in biology

Reece, Steven Y.; Hodgkiss, Justin M.; Stubbe, JoAnne; Nocera, Daniel G.

doi:10.1098/rstb.2006.1874

Cited by 268 publications

(347 citation statements)

References 107 publications

(135 reference statements)

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“…The mechanism of activation by these complexes is highly substrate dependent and may proceed by initial HAT, electron transfer, or hydride transfer [79]. On the other hand, prior reduction of this species to the Mn IV -Mn III allows for HAT reactivity: (phen) 2 Mn(μ-O) 2 Mn(phen) 2 ] 3+ may undergo two HAT events to form the bridged hydroxo species (phen) 2 Mn(μ-OH) 2 Mn(phen) 2 ] 3+ . Based on thermochemical data, addition of the first hydrogen atom to the bis-oxo species has an O-H BDFE of 79 kcal mol −1 , where addition of the second hydrogen atom to form the bis-hydroxo species has an O-H BDFE of 75 kcal mol −1 [80].…”

Section: Metal-oxo Complexes For C-h Bond Oxidationmentioning

confidence: 99%

“…'Proton-coupled electron transfer' (PCET) describes any elementary step (or series of elementary steps) in which both a proton and an electron are exchanged [1][2][3][4][5][6][7][8][9]. Within this broad definition, further distinctions may be drawn: if the proton and electron move simultaneously, the elementary step is referred to as a concerted PCET.…”

Section: Introductionmentioning

confidence: 99%

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Proton-Coupled Electron Transfer in Organic Synthesis: Fundamentals, Applications, and Opportunities

Miller

Tarantino

Knowles

2016

Topics in Current Chemistry Collections

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Proton-coupled electron transfers (PCETs) are unconventional redox processes in which both protons and electrons are exchanged, often in a concerted elementary step. While PCET is now recognized to play a central a role in biological redox catalysis and inorganic energy conversion technologies, its applications in organic synthesis are only beginning to be explored. In this chapter we aim to highlight the origins, development and evolution of PCET processes most relevant to applications in organic synthesis. Particular emphasis is given to the ability of PCET to serve as a non-classical mechanism for homolytic bond activation that is complimentary to more traditional hydrogen atom transfer processes, enabling the direct generation of valuable organic radical intermediates directly from their native functional group precursors under comparatively mild catalytic conditions. The synthetically advantageous features of PCET reactivity are described in detail, along with examples from the literature describing the PCET activation of common organic functional groups.

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Section: Metal-oxo Complexes For C-h Bond Oxidationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Proton-Coupled Electron Transfer in Organic Synthesis: Fundamentals, Applications, and Opportunities

Miller

Tarantino

Knowles

2016

Topics in Current Chemistry Collections

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“…The production of the oxo is derived from the ability of the Hangman to perform PCET (challenge II; Liu & Nocera 2005;Hodgkiss et al 2006;Yang et al 2006;Soper et al 2007;Yang & Nocera 2007). The importance of the PCET mechanism in the activation of water and other small molecules has been presented in a recent Philosophical Society Discussion (Reece et al 2006). In short, the pendent H C donor group in the Hangman system exerts control over the PCET production of the electrophilic oxo from peroxide intermediates by coupling PT to internal 2e K redox events of the redox (salen or porphyrin) cofactor (Yang et al 2006;Rosenthal et al 2007;Soper et al 2007;Yang & Nocera 2007).…”

Section: Experimental Realization Of Metal-oxo Cofactors In Differentmentioning

confidence: 99%

A ligand field chemistry of oxygen generation by the oxygen-evolving complex and synthetic active sites

Betley

Surendranath

Childress

et al. 2007

Phil. Trans. R. Soc. B

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Oxygen-oxygen bond formation and O 2 generation occur from the S 4 state of the oxygen-evolving complex (OEC). Several mechanistic possibilities have been proposed for water oxidation, depending on the formal oxidation state of the Mn atoms. All fall under two general classifications: the AB mechanism in which nucleophilic oxygen (base, B) attacks electrophilic oxygen (acid, A) of the Mn 4 Ca cluster or the RC mechanism in which radical-like oxygen species couple within OEC. The critical intermediate in either mechanism involves a metal oxo, though the nature of this oxo for AB and RC mechanisms is disparate. In the case of the AB mechanism, assembly of an even-electron count, high-valent metal-oxo proximate to a hydroxide is needed whereas, in an RC mechanism, two odd-electron count, high-valent metal oxos are required. Thus the two mechanisms give rise to very different design criteria for functional models of the OEC active site. This discussion presents the electron counts and ligand geometries that support metal oxos for AB and RC O-O bond-forming reactions. The construction of architectures that bring two oxygen functionalities together under the purview of the AB and RC scenarios are described.

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“…41,42 The studies on these Hangman porphyrins and salen macrocycles clearly demonstrate that exceptional O-O bond catalysis may be achieved when redox and proton transfer properties of a cofactor are controlled independently. A key requirement is that the proton transfer distance is kept short, which is accomplished by orthogonalizing redox and proton transfer coordinates 53 in the Hangman construct. The benefit of this approach is that a multifunctional O-O bond activity of a single redox scaffold is achieved by additionally controlling the proton equivalency at the redox platform.…”

Section: Electron Transfer In O-o Bond Activation Rosenthal and Noceramentioning

confidence: 99%

Role of Proton‐Coupled Electron Transfer in O—O Bond Activation

Rosenthal

Nocera

2007

ChemInform

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The selective reduction of oxygen to water requires four electrons and four protons. The design of catalysts that promote oxygen reduction therefore requires the management of both electron and proton inventories. Pacman and Hangman porphyrins provide a cleft for oxygen binding, a redox shuttle for oxygen reduction, and functionality for tuning the acid-base properties of bound oxygen and its intermediates. With proper control of the proton-coupled electron transfer events, O-O bond breaking of oxygen, and more generally oxygenated substrates, may be achieved with high efficiencies. The rule set developed for oxygen reduction may be applied to a variety of other small molecule activation reactions of consequence to energy conversion.

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Proton-coupled electron transfer: the mechanistic underpinning for radical transport and catalysis in biology

Cited by 268 publications

References 107 publications

Proton-Coupled Electron Transfer in Organic Synthesis: Fundamentals, Applications, and Opportunities

Proton-Coupled Electron Transfer in Organic Synthesis: Fundamentals, Applications, and Opportunities

A ligand field chemistry of oxygen generation by the oxygen-evolving complex and synthetic active sites

Role of Proton‐Coupled Electron Transfer in O—O Bond Activation

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