PN<sup>3</sup>(P)-Pincer Complexes: Cooperative Catalysis and Beyond

Li, Huaifeng; Gonçalves, Théo P.; Lupp, Daniel; Huang, Kuo‐Wei

doi:10.1021/acscatal.8b04495

Cited by 97 publications

(74 citation statements)

References 115 publications

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“…In 2011, Nozaki and co-workers first investigated the PNP-ligated iridium trihydride complex 13 dehydrogenation behavior in the idea of reversible H 2 fixation, and the H 2 gas was measured by water replacement to provide a TON of 890 (Figure 7). [8a] As the hydrogen transfer of ketones was demonstrated using the RuÀ PN 3 (P) pincer complexes, [35] it was not a surprise that the FA dehydrogenation could also proceed. [9m,r,36] This well-defined PN 3 -Pincer Ru catalytic system (14) can efficiently and selectively liberate H 2 from FA under mild conditions without CO and reached a TOF of 7,000 h À 1 and a TON more than 1.1 million during a long lifetime over 150 hours.…”

Section: Catalysts With a Pincer-type Ligandmentioning

confidence: 99%

An Update on Formic Acid Dehydrogenation by Homogeneous Catalysis

Guan

Pan

Zhang

et al. 2020

Chemistry An Asian Journal

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Formic acid (FA) has been extensively studied as one of the most promising hydrogen energy carriers today. The catalytic decarboxylation of FA ideally leads to the formation of CO2 and H2 that can be applied in fuel cells. A large number of transition‐metal based homogeneous catalysts with high activity and selectivity have been reported for the selective FA dehydrogentaion. In this review, we discussed the recent development of C,N/N,N‐ligand and pincer ligand‐based homogeneous catalysts for the FA dehydrogenation reaction. Some representative catalysts are further evaluated by the CON/COF assessment (catalyst on‐cost number)/(catalyst on‐cost frequency). Conclusive remarks are provided with future challenges and opportunities.

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Section: Catalysts With a Pincer-type Ligandmentioning

confidence: 99%

An Update on Formic Acid Dehydrogenation by Homogeneous Catalysis

Guan

Pan

Zhang

et al. 2020

Chemistry An Asian Journal

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“…[13] Kundu and co-workers demonstrated that Ru complexes bearing N6,N6 0 -dimethyl-2,2'-bipyridine-6,6'diamine ligand efficiently catalyzed α-alkylation of arylacetonitriles with alcohols. [14] Recently, Ru catalyst based on tridentate bipyridyl imidazoline catalyzed analogous reaction was reported by Song et al [15] Metal-ligand cooperation (MLC) [27][28][29][30][31][32] plays an important role in catalysis. It can dramatically promote the catalytic activity applied in borrowing hydrogen catalysis using ligands containing functional groups such as NH [33][34][35][36][37] and OH [38][39][40] .…”

Section: Introductionmentioning

confidence: 99%

“…This has potential benefits for electronic transfer, which is important for metal-ligand cooperation. [27,28] The color-tuning of iridium complexes bearing 2-phenylbenzothiazole ligands has been achieved by changing the chromophore and/or groups on the benzothiazole moiety and/or phenyl ring, implying their prior properties for easy structural modification and tuneable electronic effect. [50][51][52][53] The catalytic activity for Suzuki cross-coupling of Pd (SCN) pincer complexes supported by thiophosphoryl-benzothiazole ligand is deeply influenced by the attached substituent group, suggesting that they could adjust catalytic reactivity.…”

Section: Introductionmentioning

confidence: 99%

Ru(II)‐^PBTNN^XN complex bearing functional 2‐(pyridin‐2‐yl)benzo[d]thiazole ligand catalyzed α‐alkylation of nitriles with alcohols

Huang

Hong

Sun

et al. 2020

Applied Organom Chemis

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Six tridentate NNN ligand precursors derived from 2‐(pyridin‐2‐yl)benzo[d]thiazole(PBT) with different linkers, PBTNNXN (X = NH, NMe, O, S) (1a–1f), have been successfully prepared. The electronic properties of PBTNNXN ligands are well tunable by differing linkers between PBT skeleton and the pyridine ring, and/or by introducing electron‐donating/withdrawing groups on the pyridine ring (R = OMe or F). The ligand precursors and representative complexes Ru (PBTNNNHN)Cl2(PPh3) (2a), Ru (PBTNNNMeN)Cl2(PPh3) (2b), and Ru (PBTNNSN)Cl2(PPh3) (2f) have been characterized by NMR spectroscopy, high‐resolution mass spectroscopy, and Fourier transform infrared (FT‐IR). The molecular structures of 1f, 2a, and 2f have been determined by X‐ray diffraction study. The results indicate that PBTNNNHN ligand in the complex presented coplanar with two five‐membered chelating rings. It should be noted that 2a featuring a NH group exhibits superior performance compared to those with other linkers (such as NMe, O, or S). A variety of heterocyclic and aromatic nitriles with aromatic and aliphatic alcohols have been explored in α‐alkylation for good to excellent yields. Based on kinetic experiments and mechanistic studies, a proposed mechanism was put forward. Ru‐H species and benzaldehyde, which was oxidized from benzyl alcohol, were detected in the catalytic cycle.

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“…Furthermore, formic acid has been identified and explored as ap otential carrier of dihydrogen. [24][25][26] Furthermore, the potentialo fp incerc omplexes as efficient electrocatalysts for CO 2 reduction under mild conditions has recently been demonstrated for Mn, [27] Ru, [28] and Ir [29,30] complexes. [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 ].…”

mentioning

confidence: 99%

“…[1,2] Homogeneous catalysts have been developed for CO 2 reduction under both electrochemical and photochemical conditions. [24][25][26] Furthermore, the potentialo fp incerc omplexes as efficient electrocatalysts for CO 2 reduction under mild conditions has recently been demonstrated for Mn, [27] Ru, [28] and Ir [29,30] complexes. [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.…”

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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PN³(P)-Pincer Complexes: Cooperative Catalysis and Beyond

Cited by 97 publications

References 115 publications

An Update on Formic Acid Dehydrogenation by Homogeneous Catalysis

An Update on Formic Acid Dehydrogenation by Homogeneous Catalysis

Ru(II)‐^PBTNN^XN complex bearing functional 2‐(pyridin‐2‐yl)benzo[d]thiazole ligand catalyzed α‐alkylation of nitriles with alcohols

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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PN3(P)-Pincer Complexes: Cooperative Catalysis and Beyond

Cited by 97 publications

References 115 publications

An Update on Formic Acid Dehydrogenation by Homogeneous Catalysis

An Update on Formic Acid Dehydrogenation by Homogeneous Catalysis

Ru(II)‐PBTNNXN complex bearing functional 2‐(pyridin‐2‐yl)benzo[d]thiazole ligand catalyzed α‐alkylation of nitriles with alcohols

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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PN³(P)-Pincer Complexes: Cooperative Catalysis and Beyond

Ru(II)‐^PBTNN^XN complex bearing functional 2‐(pyridin‐2‐yl)benzo[d]thiazole ligand catalyzed α‐alkylation of nitriles with alcohols

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