Hydrogenation of Quinolines Using a Recyclable Phosphine‐Free Chiral Cationic Ruthenium Catalyst: Enhancement of Catalyst Stability and Selectivity in an Ionic Liquid

Zhou, Haifeng; Li, Zhiwei; Wang, Zhijian; Wang, Tianli; Xu, Lijin; He, Yong; Fan, Qing‐Hua; Pan, Jie; Gu, Lian‐Quan; Chan, Albert S. C.

doi:10.1002/anie.200802237

Cited by 302 publications

(68 citation statements)

References 66 publications

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“…In addition, ruthenium and rhodium complexes were successively introduced to the asymmetric hydrogenation of quinolines by Fan [78,79] and Xiao [80] groups with phosphine-free ligands, and the catalysts were air stable (Fig. 11).…”

Section: Adventure In Asymmetric Hydrogenationmentioning

confidence: 99%

“…11). Fan and coworkers reported the first phosphine-free cationic Ru/Ts-DPEN catalyst in asymmetric hydrogenation of quinolines with unprecedented reactivity and high enantioselectivity [78]. Subsequently, they found this catalytic system was effective under more environmentally friendly solvent-free or highly concentrated conditions [79].…”

Section: Adventure In Asymmetric Hydrogenationmentioning

confidence: 99%

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Adventure in Asymmetric Hydrogenation: Synthesis of Chiral Phosphorus Ligands and Asymmetric Hydrogenation of Heteroaromatics

Wang

et al. 2011

Asymmetric Catalysis From a Chinese Perspective

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Catalytic asymmetric hydrogenations of prochiral unsaturated compounds, such as olefins, ketones, and imines, have been intensively studied and are considered as a versatile method of the synthesis of chiral compounds due to atom economy and operational simplicity. Since 2002, we mainly focused on synthesis of new phosphorus ligands, asymmetric hydrogenation of heteroaromatic compounds and palladium-catalyzed asymmetric hydrogenation. Significant contribution was made in the Dalian Institute of Chemical Physics. In this chapter, we hope to share our experience and adventure in the development of chiral monophosphite ligands and phosphine-phosphoramidite ligands, asymmetric hydrogenation of heteroaromatic compounds, and the development of new homogeneous palladium catalytic hydrogenation system, which have a wide range of applications in synthesis of chiral compounds.

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Section: Adventure In Asymmetric Hydrogenationmentioning

confidence: 99%

Section: Adventure In Asymmetric Hydrogenationmentioning

confidence: 99%

Adventure in Asymmetric Hydrogenation: Synthesis of Chiral Phosphorus Ligands and Asymmetric Hydrogenation of Heteroaromatics

Wang

et al. 2011

Asymmetric Catalysis From a Chinese Perspective

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“…Chan and coworkers used [(p-cymene)Ru(26)(OTf)], an analogue of the iridium catalyst [Cp Ã Ir(OTf) (26)] (see Table 6.4, entry 17), to hydrogenate various 2-substituted quinolines in [BMIM] þ [PF 6 ] À solution [131]. Remarkably, the ionic liquid improved both the stability and enantioselectivity of the catalyst (compared to MeOH solution); it could be stored in [BMIM] þ [PF 6 ] À solution under air for a month without losing activity or enantioselectivity.…”

Section: Quinolines and Isoquinolinesmentioning

confidence: 99%

Chiral Amines from Transition‐Metal‐Mediated Hydrogenation and Transfer Hydrogenation

Church¹,

Andersson²

2010

Chiral Amine Synthesis

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This chapter focuses specifically on the synthesis of amines of the form HNR Ã R 1 , NR Ã R 1 R 2 , and HN(X)R Ã (R Ã ¼ chiral alkyl group; R 1 , R 2 ¼ alkyl or aryl groups; X ¼ heteroatom such as N, S, or P) via the asymmetric hydrogenation of imines, enamines, and iminiums. Thus, we will discuss the formation of amines that have (i) chirality a to the nitrogen, and (ii) no carbonyl group a to nitrogen. Many reported examples of this reaction use substrates with C¼N moieties in a ring, so cyclic amines will receive considerable attention. We will discuss in detail the formation of chiral amines using the asymmetric reduction of aza-aromatic substrates, which has been a popular topic in recent years, and will cover the use of N-carbonyl groups to facilitate this reaction. However, the hydrogenations of nonaromatic a,b-unsaturated amides will not be discussed. Though chiral amides (HN(R Ã )C(O)R 1 ) can be produced highly enantioselectively using these reactions, the sheer number of publications on the topic places it outside the scope of this chapter. These hydrogenations are, however, well covered in a number of existing books and review articles [1]. In addition, we will not cover the related process, reductive amination, which is discussed elsewhere in this book.6.2 Chiral Amines with a Disubstituted Nitrogen Atom, HNR Ã R 1 Direct Asymmetric Hydrogenation of Alkyl-and Aryl-Substituted IminesThough less developed than the analogous reductions of olefins and ketones, the iridium-catalyzed asymmetric hydrogenation of imines (especially N-benzyl and Naryl amines) has received considerable study. It has therefore been the subject of

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“…"Ionic hydrogenations" and also transfer hydrogenations with similar polar mechanistic background are presently mainly ruthenium and iridium based. [12][13][14][15][16][17][18][19] It is anticipated that related non-noble metal catalyses could were prepared and treated with NaHBEt 3 to obtain the corresponding hydride species WH(NO)(η 2 3 (9a) and L = PMe 3 (9b)] were produced from 7a and 7b by the reaction with NaHBEt 3 . Hydride 8b turned out to be the most stable hydride complex in the given series.…”

Section: Introductionmentioning

confidence: 99%

Protonic–Hydridic Bifunctionality: The Protonic (2‐Aminoethyl)dimethylphosphane Ligand in Nitrosyl Tungsten Hydride Complexes

et al. 2009

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The chemistry of nitrosyl tungsten hydrides bearing the (2‐aminoethyl)dimethylphosphane ligand (edmp) with an acidic NH functionality was studied. Such complexes were targeted by applying the reaction of WCl3(NO)(CH3CN)2 with edmp, which gave [WCl2(NO)(η2‐edmp)2][Cl] (1a) and [WCl2(NO)(η2‐edmp)2][BPh4] (1b). Complex 1b was treated with Zn to produce [W(H)(Cl)(NO)(η2‐edmp)2][BPh4] (2b). Subsequent attempts with the use of WCl(NO)[P(OMe)3]4 and edmp as starting materials produced {W(NO)(η2‐edmp)2[P(OMe)3]}[Cl] (3a) at 85 °C and [W(H)(Cl)(NO)(η2‐edmp)2][Cl] (2a) at 120 °C. Substitution of the P(OMe)3 ligand in {W(η2‐edmp)2(NO)[P(OMe)3]}[BPh4] (3b) with CO afforded [W(CO)(η2‐edmp)2(NO)][BPh4] (4b). Complex 4b was treated withNaHBEt3, resulting in a dihydride product [W(CO)trans‐(η1‐edmp)2(H)2(NO)]Na (4c). The chlorido complexes containing one η2‐edmp ligand WCl(NO)(η2‐edmp)(PMe3)2 (5a), WCl(NO)(η2‐edmp)(CO)(PMe3) (6a), WCl(NO)(η2‐edmp)[P(OMe)3]2 (5b), and WCl(NO)(CO)(η2‐edmp)[P(OMe)3] (6b) were prepared and treated with NaHBEt3 to obtain the corresponding hydride species WH(NO)(η2‐edmp)[P(OMe)3]2 (8b), WH(NO)(CO)(η2‐edmp)(PMe3) (7a), and WH(NO)(CO)(η2‐edmp)[P(OMe)3] (7b). The initially formed WH(NO)(η2‐edmp)(PMe3)2 (8a) was spontaneously transformed into the amide complex W(NO)(CO)(NHCH2CH2PMe2)(PMe3) (11a) with loss of H2. The anionic dihydride products [W(H)2(η1‐edmp)(NO)L2]Na [L = PMe3 (9a) and L = PMe3 (9b)] were produced from 7a and 7b by the reaction with NaHBEt3. Hydride 8b turned out to be the most stable hydride complex in the given series. NMR spectroscopic experiments and deuterium labeling showed that 8b coexists in equilibrium with corresponding dihydrogen amide complex 10b. The structures of compounds 1a, 2b, 3a, 4b, 5b, 6a, and 6b were studied by single‐crystal X‐ray diffraction.(© Wiley‐VCH Verlag GmbH & Co. KGaA, 69451 Weinheim, Germany, 2009)

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Hydrogenation of Quinolines Using a Recyclable Phosphine‐Free Chiral Cationic Ruthenium Catalyst: Enhancement of Catalyst Stability and Selectivity in an Ionic Liquid

Cited by 302 publications

References 66 publications

Adventure in Asymmetric Hydrogenation: Synthesis of Chiral Phosphorus Ligands and Asymmetric Hydrogenation of Heteroaromatics

Adventure in Asymmetric Hydrogenation: Synthesis of Chiral Phosphorus Ligands and Asymmetric Hydrogenation of Heteroaromatics

Chiral Amines from Transition‐Metal‐Mediated Hydrogenation and Transfer Hydrogenation

Protonic–Hydridic Bifunctionality: The Protonic (2‐Aminoethyl)dimethylphosphane Ligand in Nitrosyl Tungsten Hydride Complexes

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