A 3.0 μs Room Temperature Excited State Lifetime of a Bistridentate Ru<sup>II</sup>−Polypyridine Complex for Rod-like Molecular Arrays

Abrahamsson, Maria; Jäger, Michael; Österman, Tomas; Eriksson, Lars E.; Persson, Petter; Becker, H. G. O.; Johansson, Olof; Hammarström, Leif

doi:10.1021/ja064262y

Cited by 203 publications

(264 citation statements)

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“…Schematic energy diagram of relevant excited and charge-separated states versus the ground state (GS) for the triads 1 a and 3 a. Triplet excited-state energies are taken from the literature. [23,35] The charge-separated-state energies are calculated from data in Table 1, as described in the text. Solid arrows mark the observed charge-separation (CS) and charge-recombination (CR) processes.…”

Section: Methodsmentioning

confidence: 99%

“…[21] As an alternative approach the trans-[RuA C H T U N G T R E N N U N G (bpy) 2 (py) 2 ] 2 + (py = pyridine) motif has been used, but it unfortunately also suffers from a short room-temperature excited-state lifetime and, additionally, poor photostability. [22] Recently, our group has detailed the rational development [23,24] and facile synthesis [25,26] of a new class of Ru II bistridentate photosensitizers, based on Ru II bis-2,6-di(quinolin-8-yl)pyridine ([RuA C H T U N G T R E N N U N G (dqp) 2 ] 2 + ). An almost perfect octahedral coordination sphere, with short and equal Ru-N dis-A C H T U N G T R E N N U N G tances, and consequently a strong ligand field is created through the use of six-membered chelates leading to photophysical properties similar to those of [RuA C H T U N G T R E N N U N G (bpy) 3 ] 2 + .…”

Section: Conversely [Rua C H T U N G T R E N N U N G (Tpy) 2 ]mentioning

confidence: 99%

“…2 + , [23] the broad band at 495 nm can be assigned to the lowest excited singlet MLCT state, and the higher bands (at 290 and 340 nm) are attributed to ligand-centred (LC) transitions. The small peak at 410 nm in the absorption spectrum of 1 a is found in all phenyl-linked complexes studied here (1 a, 1 b, 2 a and 2 b).…”

Section: Electrochemistrymentioning

confidence: 99%

“…2.35 eV according to the literature. [35] Thus, energy transfer from the 3 MLCT excited state (E 00 = 1.84 eV for [RuA C H T U N G T R E N N U N G (dqp) 2 ] 2 + in a MeOH/EtOH glass) [23] to form the quinone triplet is a considerably uphill process, and not a likely quenching mechanism. From the electrochemistry data given in Table 1, the driving force for the electron transfer is approximately DG [ 45] In principle, the PTZ + Ru II Q À charge-separated state could be formed through two alternative routes, reductive quenching [Eq.…”

Section: Wwwchemeurjorgmentioning

confidence: 99%

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Vectorial Electron Transfer in Donor–Photosensitizer–Acceptor Triads Based on Novel Bis‐tridentate Ruthenium Polypyridyl Complexes

Kumar

Karlsson

Streich

et al. 2010

Chemistry A European J

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The first examples of rodlike donor-photosensitizer-acceptor arrays based on bis-2,6-di(quinolin-8-yl)pyridine Ru(II) complexes 1a and 3a for photoinduced electron transfer have been synthesized and investigated. The complexes are synthesized in a convergent manner and are isolated as linear, single isomers. Time-resolved absorption spectroscopy reveals long-lived, photoinduced charge-separated states (tau(CSS) (1a)=140 ns, tau(CSS) (3a)=200 ns) formed by stepwise electron transfer. The overall yields of charge separation (> or = 50% for complex 1a and > or = 95% for complex 3a) are unprecedented for bis-tridentate Ru(II) polypyridyl complexes. This is attributed to the long-lived excited state of the [Ru(dqp)(2)](2+) complex combined with fast electron transfer from the donor moiety following the initial charge separation. The rodlike arrangement of donor and acceptor gives controlled, vectorial electron transfer, free from the complications of stereoisomeric diversity. Thus, such arrays provide an excellent system for the study of photoinduced electron transfer and, ultimately, the harvesting of solar energy.

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Section: Methodsmentioning

confidence: 99%

Section: Conversely [Rua C H T U N G T R E N N U N G (Tpy) 2 ]mentioning

confidence: 99%

Section: Electrochemistrymentioning

confidence: 99%

Section: Wwwchemeurjorgmentioning

confidence: 99%

See 2 more Smart Citations

Vectorial Electron Transfer in Donor–Photosensitizer–Acceptor Triads Based on Novel Bis‐tridentate Ruthenium Polypyridyl Complexes

Kumar

Karlsson

Streich

et al. 2010

Chemistry A European J

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“…[7][8][9][10] As a consequence of all six-membered chelates, the dqp ligands adopt nonplanar helical conformations. The conformation of one ligand predetermines the conformation of the second ligand (either l,l or d,d enantiomers) leading to intramolecular p-stacking between quinoline pairs.…”

Section: H T U N G T R E N N U N G Ands Mer-[rua C H T U N G T R E Nmentioning

confidence: 99%

Resolution of Conformationally Chiral mer‐[Ru(dqp)₂]²⁺ and Crystallographic Analysis of [δ,δ‐Ru(dqp)₂][Δ‐TRISPHAT]₂ (dqp=2,6‐Di(quinolin‐8‐yl)pyridine; TRISPHAT=Tris(tetrachlorocatecholate)phosphate)

Sharma

Lombeck

Eriksson

et al. 2010

Chemistry A European J

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Photosynthesis, Artificial: Progress in Swedish Consortium

Ott

Styring

Hammarström

et al. 2005

Encyclopedia of Inorganic Chemistry

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Mimicking energy conversion processes in nature using molecular systems is a promising approach for future solar fuel production. The Swedish Consortium for Artificial Photosynthesis is involved in the design, preparation and functional study of many of the key components needed for a homogeneous approach to artificial photosynthesis, building on principles from photosystem II (PSII) and [FeFe] hydrogenases. Ruthenium(II) polypyridyl complexes have played an important role as photosensitizers. Several strategies have been developed for their preparation, and a novel approach to improve the photophysical properties of bistridentate complexes involving six‐membered chelates for more octahedral coordination was recently introduced. The [Ru(dqp) 2 ] 2+ complexes (dqp is 2,6‐di(quinolin‐8‐yl)pyridine) combine the desired structural properties for easy access to linear donor–acceptor assemblies, while maintaining microsecond luminescent lifetimes of their 3 MLCT (metal‐to‐ligand charge transfer) excited states. The synthesis of these chromophores is now well established, and the recent realization of donor–photosensitizer–acceptor assemblies shows that photoproduced charge‐separated states can be formed in high yields (ϕ ≥ 95%). Beyond such single‐photon/single‐electron events, charge accumulation at potential catalytic sites is crucial for multielectron redox reactions. Covalently linked Ru II Mn x ( x = 1,2) complexes as PSII mimics have been investigated to understand chromophore–quencher (Mn quenchers) interactions, to promote desired electron transfer processes, and suppress undesired competing reactions. The Mn units often have large inner reorganization energies upon oxidation or reduction, which make them unusually slow electron donors and/or acceptors in photoinduced charge‐separation schemes. Charge accumulation and water splitting, however, require the management of both protons and electrons, which controls the electron transfer processes by proton‐coupled electron transfer (PCET). Studies on Ru II Tyr complexes incorporating pendant bases led to an understanding of the effect of hydrogen‐bonding on electron transfer rates. In analogy to the electron donor side, bioinorganic models of the [FeFe] H 2 ase active site are targeted for the electron acceptor side, with the ultimate goal to realize molecular catalysts that produce H 2 at similar high rates and low overpotential as the enzymes. Certain ligand sets create basic sites around the Fe centers that are protonated in the presence of acid and are thus models of late intermediates in the enzymatic catalytic cycle. Furthermore, synthetic Fe 2 complexes catalyze the electrochemical reduction of protons. In combination with a photosensitizer, they can also be used in photochemical schemes and are currently used to produce H 2 photochemically, with turnover rates up to 200.

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A 3.0 μs Room Temperature Excited State Lifetime of a Bistridentate Ru^II−Polypyridine Complex for Rod-like Molecular Arrays

Cited by 203 publications

References 19 publications

Vectorial Electron Transfer in Donor–Photosensitizer–Acceptor Triads Based on Novel Bis‐tridentate Ruthenium Polypyridyl Complexes

Vectorial Electron Transfer in Donor–Photosensitizer–Acceptor Triads Based on Novel Bis‐tridentate Ruthenium Polypyridyl Complexes

Resolution of Conformationally Chiral mer‐[Ru(dqp)₂]²⁺ and Crystallographic Analysis of [δ,δ‐Ru(dqp)₂][Δ‐TRISPHAT]₂ (dqp=2,6‐Di(quinolin‐8‐yl)pyridine; TRISPHAT=Tris(tetrachlorocatecholate)phosphate)

Photosynthesis, Artificial: Progress in Swedish Consortium

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A 3.0 μs Room Temperature Excited State Lifetime of a Bistridentate RuII−Polypyridine Complex for Rod-like Molecular Arrays

Cited by 203 publications

References 19 publications

Vectorial Electron Transfer in Donor–Photosensitizer–Acceptor Triads Based on Novel Bis‐tridentate Ruthenium Polypyridyl Complexes

Vectorial Electron Transfer in Donor–Photosensitizer–Acceptor Triads Based on Novel Bis‐tridentate Ruthenium Polypyridyl Complexes

Resolution of Conformationally Chiral mer‐[Ru(dqp)2]2+ and Crystallographic Analysis of [δ,δ‐Ru(dqp)2][Δ‐TRISPHAT]2 (dqp=2,6‐Di(quinolin‐8‐yl)pyridine; TRISPHAT=Tris(tetrachlorocatecholate)phosphate)

Photosynthesis, Artificial: Progress in Swedish Consortium

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A 3.0 μs Room Temperature Excited State Lifetime of a Bistridentate Ru^II−Polypyridine Complex for Rod-like Molecular Arrays

Resolution of Conformationally Chiral mer‐[Ru(dqp)₂]²⁺ and Crystallographic Analysis of [δ,δ‐Ru(dqp)₂][Δ‐TRISPHAT]₂ (dqp=2,6‐Di(quinolin‐8‐yl)pyridine; TRISPHAT=Tris(tetrachlorocatecholate)phosphate)