Function-Integrated Ru Catalyst for Photochemical CO<sub>2</sub> Reduction

Lee, Sze Koon; Kondo, Mio; Okamura, Masaya; Enomoto, Takafumi; Nakamura, Go; Masaoka, Shigeyuki

doi:10.1021/jacs.8b09933

Cited by 77 publications

(71 citation statements)

References 43 publications

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“…Notably the current studies have been conducted at lower concentrations of catalyst than the prior studies which is in line with current literature trends (1 µ m vs. 100 µ m ). [2c], [4c], Evaluating catalysts at lower concentration is desirable to avoid SD limited catalysis since the solubility limit of BIH in MeCN is around 10 m m . The observed trend in catalyst TON is Ru OMe > Ru Me > Ru 3OMe > Ru H > Ru NPh2 >> Ru NMe2 > Ru OH (Figure , Table ).…”

Section: Resultsmentioning

confidence: 99%

Structure Function Relationships in Ruthenium Carbon Dioxide Reduction Catalysts with CNC Pincers Containing Donor Groups

Das

Nugegoda

et al. 2020

Eur J Inorg Chem

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Seven ruthenium catalysts with the general formula [(CNC)Ru(CH 3 CN) 2 Cl]OTf have been used to understand structure function relationships in the sensitized photocatalytic CO 2 reduction reaction. Herein, CNC is a pincer ligand containing imidazole-based N-heterocyclic carbenes (NHCs) attached to a central pyridyl ring with R groups at the 3-or 4-position. Two new complexes (R = 3-OMe, 4-NPh 2) have been fully characterized by analytical and spectroscopic methods and single-crystal X-ray diffraction. Furthermore, three previously synthesized complexes (R = 4-Me, 4-NMe 2 , and 4-OH) are used for photoca-[a

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Section: Resultsmentioning

confidence: 99%

Structure Function Relationships in Ruthenium Carbon Dioxide Reduction Catalysts with CNC Pincers Containing Donor Groups

Das

Nugegoda

et al. 2020

Eur J Inorg Chem

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“…Most studies on visible-light driven photoredoxc atalysis completely ignore the efficiency aspect (i.e.,t he overall quantum yields) and merely focus on the feasibility to use visible light as energy input. In addition to photoredox catalysis, the M À generation is important for many photochemical carbon dioxide reduction [12,[81][82][83] and hydrogen production [13,[84][85][86][87][88][89][90][91][92] mechanisms, demonstrating that the new mechanism introduced in this manuscript has severalp ossible application areas. Our study on the heavily underexplored inherente ffi-ciency of photoinduced electron transfer events might trigger furtherq uantitative investigations that could contribute to a better understanding of how to use photons moree fficiently, [93] which could ultimately result in more sustainability in photochemistry.…”

Section: Discussionmentioning

confidence: 99%

“…Visible-light photoredox catalysis as av ersatile tool in synthetic organic chemistry has attracted increasing attention in recent years, [1][2][3][4][5][6][7][8] and research on solar fuels continues to explore the possibility of harvesting sunlight to drive chemical reactions. [9][10][11][12][13] About half of the chemical syntheses in these fields are reductivet ransformations, with the most prominentk ey intermediates for substrate activation being one-electron-reduced Ru and Ir metal complexes.H owever,t he direct generation of thesei ntermediates via photoreduction of excited triplet states is usually inefficient, which is due to the heavy atom effect. Hence, as ubstantial part of the photons absorbed by the catalyst cannotb eu sed productively,a dversely affecting the sustainabilitya spect connected with photocatalysis.…”

Section: Introductionmentioning

confidence: 99%

Controlling Spin‐Correlated Radical Pairs with Donor–Acceptor Dyads: A New Concept to Generate Reduced Metal Complexes for More Efficient Photocatalysis

Neumann

Wenger

Kerzig

2021

Chemistry A European J

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One-electron reduced metal complexes derived from photoactive ruthenium or iridium complexes are important intermediates for substrate activation steps in photoredox catalysis and for the photocatalytic generation of solar fuels. However,o wing to the heavy atom effect, direct photochemical pathways to these key intermediates suffer from intrinsic efficiency problems resulting from rapid geminate recombination of radical pairs within the so-called solvent cage. In this study,w ep repared and investigated molecular dyads capable of producing reduced metal complexes via an indirect pathway relyingo nas equence of energy and electron transfer processes between aR uc omplex and ac ovalently connected anthracene moiety.O ur test reaction to establish the proof-of-concept is the photochem-ical reduction of ruthenium(tris)bipyridine by the ascorbate dianion as sacrificial donor in aqueous solution. The photochemicalk ey step in the Ru-anthracene dyads is the reduction of ap urely organic (anthracene) triplet exciteds tate by the ascorbate dianion, yielding as pin-correlated radical pair whose (unproductive) recombination is strongly spin-forbidden. By carrying out detailed laser flash photolysis investigations, we provide clear evidence for the indirect reduced metal complex generation mechanism and show that this pathway can outperform the conventionald irect metal complex photoreduction. The furthero ptimization of our approach involving relativelys imple molecular dyads might result in novel photocatalysts that convert substrates with unprecedented quantum yields.

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“…Success in this endeavor requires confronting the inherent stabilitya nd low thermodynamic value of CO 2 and would transform this ubiquitous waste product into av aluable feedstock. [15,16] Recently,p incer ligand-supported catalysts of Fe, Co, Ru, and Ir have been shown to have excellent activity and selectivity for hydrogenation of CO 2 . Furthermore, formic acid has been identified and explored as ap otential carrier of dihydrogen.…”

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confidence: 99%

“…For example, photocatalytic formation of formic acid, at wo-electron reductionp roduct of CO 2 ,w ould yield ac ommodity chemical and al iquid fuel. [15,16] Recently,p incer ligand-supported catalysts of Fe, Co, Ru, and Ir have been shown to have excellent activity and selectivity for hydrogenation of CO 2 . [1,2] Homogeneous catalysts have been developed for CO 2 reduction under both electrochemical and photochemical conditions.…”

mentioning

confidence: 99%

Visible‐Light Photocatalytic Reduction of CO₂ to Formic Acid with a Ru Catalyst Supported by N,N′‐Bis(diphenylphosphino)‐2,6‐diaminopyridine Ligands

et al. 2019

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Visible-light photocatalytic CO 2 reduction is carried out by using aR u II complex supportedb yN,N'-bis(diphenylphosphino)-2,6-diaminopyridine( "PNP")l igands, an unprecedented molecular architecture for this reaction that breaks the longstanding domination of a-diimine ligands. These competent catalysts transform CO 2 into formic acid with high selectivity and turnover number.Aproposed mechanism, with combined electron transfer and catalytic cycles, models the experimental rate of formic acid production.Designing and assembling catalysts that can utilize the energy of visible light to overcome the barriers to reduce CO 2 is an important fundamentala nd technological challenge. Success in this endeavor requires confronting the inherent stabilitya nd low thermodynamic value of CO 2 and would transform this ubiquitous waste product into av aluable feedstock. For example, photocatalytic formation of formic acid, at wo-electron reductionp roduct of CO 2 ,w ould yield ac ommodity chemical and al iquid fuel. Furthermore, formic acid has been identified and explored as ap otential carrier of dihydrogen. [1,2] Homogeneous catalysts have been developed for CO 2 reduction under both electrochemical and photochemical conditions. [3][4][5][6] Photocatalysis is ap articularly appealing approacha s it relies on an essentially limitless and clean solar energy source.P hotocatalytic systemsc onsisto fi ntegrated components that include ap hotosensitizer (PS)f or harvesting the energy of the light, an electron donor (ED)t hat provides electrons for the reduction, and ac atalyst (CAT)t hat is as ite for the transformation of CO 2 .T oo ur knowledge,s ince their discovery in 1985, [7] all of the reported molecular photocatalysts based on Ru II have used a-diimine supporting ligandsa nd these speciesh ave fallen into two broad groups.O ne class are bis(a-diimine) speciesr epresentedb ycis-[Ru(N^N) 2 (CO) 2 ] 2 + [8][9][10][11] and the other are mono(a-diimine) catalysts represented by cis,trans-[Ru(N^N)(CO) 2 Cl 2 ]. [12][13][14] Althoughavariety of substituents on the a-diimine ligands have been productively explored to improvec atalystp erformance, given the maturity of this field, ab roader variationo fm olecular architecture is required to provide new insights and stimulate new concepts in this field. Ligand variation and discoverya re ac entral challenge in catalysis and expanding Ru-based photocatalysts beyond the restrictions of a-diimine support is certainly warranted. Support for this approachc omes from av ery recent report on the use of ap hotocatalytic phosphine-substituted Ru II terpyridine complex-trans-[Ru(tpy)(8-quinolyl(diphenyl)phosphine)-(MeCN)] 2 + -that functions as both ap hotosensitizer andacatalyst for CO 2 reduction. [15,16] Recently,p incer ligand-supported catalysts of Fe, Co, Ru, and Ir have been shown to have excellent activity and selectivity for hydrogenation of CO 2 . [17][18][19][20][21][22][23] Pincer-supported ruthenium complexes can catalyze hydrogenation of CO 2 to yield formate, as wella st he ...

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Function-Integrated Ru Catalyst for Photochemical CO₂ Reduction

Cited by 77 publications

References 43 publications

Structure Function Relationships in Ruthenium Carbon Dioxide Reduction Catalysts with CNC Pincers Containing Donor Groups

Structure Function Relationships in Ruthenium Carbon Dioxide Reduction Catalysts with CNC Pincers Containing Donor Groups

Controlling Spin‐Correlated Radical Pairs with Donor–Acceptor Dyads: A New Concept to Generate Reduced Metal Complexes for More Efficient Photocatalysis

Visible‐Light Photocatalytic Reduction of CO₂ to Formic Acid with a Ru Catalyst Supported by N,N′‐Bis(diphenylphosphino)‐2,6‐diaminopyridine Ligands

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Function-Integrated Ru Catalyst for Photochemical CO2 Reduction

Cited by 77 publications

References 43 publications

Structure Function Relationships in Ruthenium Carbon Dioxide Reduction Catalysts with CNC Pincers Containing Donor Groups

Structure Function Relationships in Ruthenium Carbon Dioxide Reduction Catalysts with CNC Pincers Containing Donor Groups

Controlling Spin‐Correlated Radical Pairs with Donor–Acceptor Dyads: A New Concept to Generate Reduced Metal Complexes for More Efficient Photocatalysis

Visible‐Light Photocatalytic Reduction of CO2 to Formic Acid with a Ru Catalyst Supported by N,N′‐Bis(diphenylphosphino)‐2,6‐diaminopyridine Ligands

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Function-Integrated Ru Catalyst for Photochemical CO₂ Reduction

Visible‐Light Photocatalytic Reduction of CO₂ to Formic Acid with a Ru Catalyst Supported by N,N′‐Bis(diphenylphosphino)‐2,6‐diaminopyridine Ligands