2017
DOI: 10.1002/chem.201701456
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Exceptionally Long‐Lived Photodriven Multi‐Electron Storage without Sacrificial Reagents

Abstract: Photo-excitation of a molecular pentad in presence of Sc 3+ in de-aerated CH 3 CN leads to a quinone dianion that is stable on the millisecond timescale. Light-driven electron accumulation on the quinone unit is sensitized by two Ru(bpy) 3 2+ complexes in an intramolecular process, which relies on covalently attached triarylamine donors rather than on sacrificial reagents. Lewis acidLewis base interactions between Sc 3+ and quinone dianion are responsible for the exceptionally long lifetime of this photoproduc… Show more

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Cited by 15 publications
(15 citation statements)
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“…23 Similarly, the interaction of Lewis acids with polar functional groups can help activate substrates that would be difficult to engage in pure PET chemistry. [24][25][26][27] We hypothesized that the photochemical hydrogenation of olens would be an ideal test ground for exploring the photo-HAT reactivity of a metal complex. Whilst alkene hydrogenation is of course an extremely well-developed eld, photochemical methods are very scarce and largely limited to substrates with strongly electron-withdrawing substituents to permit typical PET chemistry, 28 or to the reduction with solvated electrons.…”
Section: Introductionmentioning
confidence: 99%
“…23 Similarly, the interaction of Lewis acids with polar functional groups can help activate substrates that would be difficult to engage in pure PET chemistry. [24][25][26][27] We hypothesized that the photochemical hydrogenation of olens would be an ideal test ground for exploring the photo-HAT reactivity of a metal complex. Whilst alkene hydrogenation is of course an extremely well-developed eld, photochemical methods are very scarce and largely limited to substrates with strongly electron-withdrawing substituents to permit typical PET chemistry, 28 or to the reduction with solvated electrons.…”
Section: Introductionmentioning
confidence: 99%
“…Ta king inspiration from these systems, more sophisticated light-harvesting units, capable of storing multiple electrons upon visible light irradiation,h ave been synthesized and studied. [20][21][22] Twoc onceptually differentm olecular designs have proven successful in storing multiple reducing equivalents in artificial photosynthetics ystems: either the system assembles multiple chromophores each of whichi ndependently transfers electrons to the acceptors ite (such as ab ridging ligand betweent wo chromophore units), [24][25][26][27][28][29][30][31][32][33][34][35][36][37] or it containsasingle protonated species [1H 2 ] 2 + .T he occurrence of PCET processes strongly lowers the reducing power of the system, precluding the use of charge photoaccumulation in [1H 2 ] 2 + to drive catalytic H 2 production.T his motivated us to search for structurally modified derivatives to store electrons at more negative potentials,e ven after protonation.U sing density functional theory( DFT) calculations, we screened electron-rich substituents ands elected the introduction of an oxime group in place of the carbonyl moiety in [1](PF 6 ) 2 .H erein we describe the process of this DFT-guidedd esign and the synthesis of the selected oxime-modified PS [2](PF 6 ) 2, together with its spectroscopic and (spectro)electrochemical characterization. Under irradiation in the presence of ap roton source, [2] 2 + transforms into the doubly protonated species [2H 2 ] 2 + ,w hichi sastronger reductant than [1H 2 ] 2 + .…”
Section: Introductionmentioning
confidence: 99%
“…Taking inspiration from these systems, more sophisticated light‐harvesting units, capable of storing multiple electrons upon visible light irradiation, have been synthesized and studied . Two conceptually different molecular designs have proven successful in storing multiple reducing equivalents in artificial photosynthetic systems: either the system assembles multiple chromophores each of which independently transfers electrons to the acceptor site (such as a bridging ligand between two chromophore units), or it contains a single chromophore and relies on a sacrificial electron donor to perform multiple excitation–accumulation cycles . In the latter case, either a single or multiple electron storage sites can be assembled adjacent to the chromophore.…”
Section: Introductionmentioning
confidence: 99%
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