手性羰基铁体系催化酮的不对称氢转移氢化

手性羰基铁络合物很少被用于芳香酮的不对称氢转移氢化.利用不同的羰基铁络合物与手性双胺双膦配体现场络合,形成手性胺膦铁催化体系.考察了它们对多种芳香酮的不对称氢转移催化氢化性能.结果表明,三核的手性胺膦铁簇合物是催化芳香酮不对称氢转移氢化的较好体系.当用三核的铁簇合物[Et₃NH]⁺[HFe₃(CO)₁₁]^-体系催化1,1-二苯基丙酮的氢化时,最高可获得98%的对映选择性.通过现场红外光谱测定,揣测羰基铁簇合物Fe₃(CO)₁₂在催化反应过程中保持三核的簇合物的簇骼不变.     

钌催化的手性苯基/苯并噻唑甲醇的转移氢化合成

以苯基/苯并噻唑甲酮为原料, 手性二胺钌络合物为催化剂, 甲酸钠为氢源, i?PrOH/H₂O(体积比1:1)为溶剂, 在室温(30 ℃)条件下, 通过不对称转移氢化, 合成了一系列手性苯基/苯并噻唑甲醇类化合物, 其对映选择性(e.e.)值高达99%. 此外, 还探讨了其它苯基/氮杂环甲酮的不对称转移氢化. 该方法具有反应条件温和、 催化剂廉价易得及操作简便等优点.     

光学活性胺膦配体的合成与在不对称催化中的应用

用邻二苯基膦苯甲醛与不同的手性二胺缩合,高产率地制备了一系列手性双胺双膦配体。这些配体分别与Ru(DMSO)4Cl2或[Rh(COD)Cl]2等反应,可制备相应的手性双胺双膦钌、铑配合物。在异丙醇溶液中,该C2-对称的手性双胺双膦钌、铑配合物是多种芳香酮不对称转移氢化的优化催化剂,反应产物手性芳香醇的转华裔经和对映选择性分别高达99%和98ee。     

聚乙二醇400-水介质中水溶性钌膦二胺催化苄叉丙酮的不对称加氢反应

在聚乙二醇400-水绿色可循环介质中,以手性二胺(S,S)-1,2-二苯基乙二胺二磺酸钠((S,S)-DPENDS)与非手性钌膦络合物([RuCl2(TPPTS)2]2)原位生成的水溶性钌膦二胺为催化剂,考察了苄叉丙酮的选择性不对称加氢反应.在优化的反应条件下,羰基加氢产物4-苯基-3-丁烯-2-醇的化学选择性和对映选择性分别为98.5%和74.3%.经正己烷萃取后,催化剂即可从产物中分离出来.循环使用5次后,4-苯基-3-丁烯-2-醇化学选择性和对映选择性没有明显下降.     

金属催化硫醚的不对称氧化研究进展

手性金属络合物催化硫醚的不对称氧化是合成手性亚砜最有效的方法. 理性设计各种手性金属络合物催化剂应用于催化对映选择性氧化潜手性硫醚反应中, 近年来引起了化学家们较大的关注. 综述了各类手性金属络合物催化剂在硫醚不对称氧化中的应用.     

新型手性环戊二烯基铑催化剂的合成及其在对映选择性碳氢键官能团化中的应用

正环戊二烯基负离子(cyclopentadienyl,Cp)及五甲基环戊二烯负离子(Cp*)拥有6个π电子,能与过渡金属通过σ键和π键形成稳定的配合物,在过渡金属催化的氢化、聚合等领域有着广泛的应用~([1]).随着不对称催化反应的发展,基于环戊二烯基负离子骨架的手性配体和催化剂也应运而生~([2]).     

手性胺膦配体在不对称催化中的应用

利用邻二苯基膦苯甲醛分别与多种手性二胺的缩合反应,设计合成了一系列新型手性四齿胺膦配体.这类多齿胺膦配体含有两个软的磷原子和两个硬的氮原子,具有丰富的配位化学性能和优秀的不对称诱导能力.本文综述了手性胺膦金属络合物催化剂在不对称转移氢化反应、氧化动力学拆分反应、烯烃的不对称环氧化反应和不对称环丙烷化反应、不对称D-A反应中的应用.     

过渡金属盐及络合物在乙苯液相氧化中的催化作用

有机化合物中的C-H键选择性官能团化是有机合成中具有挑战性的课题之一。在不同的氧源(如H₂O₂、NaOCl、TBHP、RCOOOH、O₂等)作用下,许多过渡金属络合物可以选择性氧化有机物[1]。显然,由于分子氧廉价易得并且在氧化过程中对环境没有污染,所以分子氧是氧化反应的最理想的氧源。由于分子氧较难活化以及选择性方面的原因,在温和条件下过渡金属催化的分子氧选择性氧化过程受到了广泛的关注[2]。有关乙苯的液相催化氧化已有一些报道,比较有代表性的有以[W₁₀O₃₂]^4-和 CoC₁₂·6H₂O为催化剂的光催化氧化过程[3,4]、负载型的Ru络合物催化剂[5]以及在己醛存在下以Fe盐或Ru盐为催化剂的氧化过程[6]。本文在温和条件下(常压、110℃), 考察了不同过渡金属盐及络合物在乙苯液相氧化中的催化作用,着重考察了催化反应机理。     

卡宾催化对亚甲基苯醌的不对称硼化反应的研究

使用商业化的手性三氮唑盐和联硼酸频哪醇酯[B₂(pin)₂],实现了N-杂环卡宾催化的对亚甲基苯醌的1,6-不对称硼加成反应.该反应条件温和,底物适用范围广,官能团耐受性好,且有良好的反应收率及对映选择性.值得注意的是,在无过渡金属存在下,即使催化剂用量降至底物的0.1 mol%,反应仍能保持高收率和高对映选择性.     

金属催化的不对称氢化反应研究进展与展望

手性过渡金属络合物催化的不对称氢化反应是合成光学活性化合物的重要方法. 本文从手性配体及手性催化剂、不对称催化新反应、新方法和新策略三个方面简要评述新世纪以来过渡金属催化的不对称氢化反应研究领域的新进展. 从新世纪初至今, 手性单磷配体得到了复兴, 出现了如MonoPhos、SiPhos、DpenPhos等高效单齿亚磷酰胺酯配体; 磷原子手性(P-手性)配体也得到了快速发展, 如BenzP*、ZhanPhos、TriFer等已成为新的高效手性双膦配体; 螺环骨架手性配体成为新世纪手性配体设计合成的亮点, 除了SiPhos、SIPHOX、SpinPHOX等高效手性螺环配体外, 手性螺环吡啶胺基磷配体SpiroPAP的铱催化剂成为目前最高效的分子催化剂. 不对称催化氢化新反应研究也取得了突破, 如非保护烯胺、杂芳环化合物及N-H亚胺的氢化等反应都实现了高对映选择性. 自组装手性催化剂、树枝状手性催化剂、铁磁性纳米负载的可回收手性催化剂, 以及“混合”配体手性催化剂等新方法和新策略也在不对称催化氢化反应中得到了应用. 然而, 手性过渡金属络合物催化的不对称氢化研究仍然充满挑战, 也期待新的突破.     

Manganese catalyzed asymmetric transfer hydrogenation of ketones

The asymmetric transfer hydrogenation (ATH) of a wide range of ketones catalyzed by manganese complex as well as chiral P_xN_y-type ligand under mild conditions was investigated. Using 2-propanol as hydrogen source, various ketones could be enantioselectively hydrogenated by combining cheap, readily available [MnBr(CO)₅] with chiral, 22-membered macrocyclic ligand (R,R,R',R')-CyP₂N₄ (L5) with 2 mol% of catalyst loading, affording highly valuable chiral alcohols with up to 95% ee.     

Further ‘tethered’ Ru(II) catalysts for asymmetric transfer hydrogenation (ATH) of ketones; the use of a benzylic linker and a cyclohexyldiamine ligand

The synthesis and characterisation of two new Ru(II) catalysts for the asymmetric transfer hydrogenation (ATH) of ketones is described. In the case of 4, the novelty lies in the use of a benzyl tethering group between the asymmetric ligand part (TsDPEN) and the η⁶-arene ring, which increases the complex rigidity. For 5, the use of a cyclohexyldiamine as a chiral ligand is described for the first time. In the ATH of ketones in formic acid/triethylamine, alcohols with ees of up to 97% were formed.     

Synthesis of Chiral Aromatic Alcohols: Use of New C2-Symmetric RhIIICp∗, RuII(cymene), or RuII(benzene) Complexes Containing Chiral Diaminocyclohexane Ligand as Asymmetric Transfer Hydrogenation Catalyst

Abstract

Twelve chiral secondary alcohols were synthesized by asymmetric transfer hydrogenation (ATH) using C₂-symmetric bis(sulfonamide) ligand (2) derived from (1R,2R)-cyclohexane-1,2-diamine and complexed with [RhCl₂Cp?]₂, [RuCl₂(cymene)]₂, or [RuCl₂(benzene)]₂ and then used in situ in the reduction of prochiral ketones. The alcohols were obtained in 85–99% yield and 90–99% enantioselectivity with isopropanol as the hydrogen source. Two-fold rate enhancement and better yields were achieved (88–99%) with 80–99% enantioselectivity using the complex [RhCl₂Cp?]₂ and aqueous sodium formate as the hydrogen source.     

Asymmetric hydrosilylation,transfer hydrogenation and hydrogenation of ketones catalyzed by iridium complexes

Iridium-based asymmetric reduction of ketones to chiral enantiomerically enriched alcohols has recently attracted attention by a number of research groups and interest in this area is growing. This review presents the different catalytic systems based on iridium complexes that have been used in asymmetric hydrosilylation, in asymmetric transfer hydrogenation (ATH) with alcohols or formic acid derivatives as reducing agents, and in asymmetric hydrogenation (H₂ as reducing agent). A large variety of chiral ligands of various denticities and bearing various combination of coordinating atoms (N, P, S, O, C, …) have been used and will be presented. The last part critically reviews the mechanistic understanding of all the above transformations with specific reference to iridium catalysts.     

The Hydrogenation/Transfer Hydrogenation Network in Asymmetric Reduction of Ketones Catalyzed by [RuCl2(binap)(pica)] Complexes

Chiral binap/pica‐Ru^II complexes (binap=(S)‐ or (R)‐2,2′‐bis(diphenylphosphino)‐1,1′‐binaphthyl; pica=α‐picolylamine) catalyze both asymmetric hydrogenation (AH) of ketones using H₂ and asymmetric transfer hydrogenation (ATH) using non‐tertiary alcohols under basic conditions. The AH and ATH catalytic cycles are linked by the metal–ligand bifunctional mechanism. Asymmetric reduction of pinacolone is best achieved in ethanol containing the Ru catalyst and base under an H₂ atmosphere at ambient temperature, giving the chiral alcohol in 97–98 % ee. The reaction utilizes only H₂ as a hydride source with alcohol acting as a proton source. On the other hand, asymmetric reduction of acetophenone is attained with both H₂ (ambient temperature) and 2‐propanol (>60 °C) with relatively low enantioselectivity. The degree of contribution of the AH and ATH cycles is highly dependent on the ketone substrates, solvent, and reaction parameters (H₂ pressure, temperature, basicity, substrate concentration, H/D difference, etc.).     

Structure effect of TsDPEN derivatives on enantioselectivity of asymmetric transfer hydrogenation

TsDPEN derivative (3,3′,5,5′-TMTsDPEN) was synthesized and applied in asymmetric transfer hydrogenation of ketones. The influence of chiral ligands’ NCCN dihedral angles to the enantioselectivities of the reaction was discussed.     

Sulfone Group as a Versatile and Removable Directing Group for Asymmetric Transfer Hydrogenation of Ketones

The sulfone functional group has a strong capacity to direct the asymmetric transfer hydrogenation (ATH) of ketones in the presence of [(arene)Ru(TsDPEN)H] complexes by adopting a position distal to the η⁶‐arene ring. This preference provides a means for the prediction of the sense of asymmetric reduction. The sulfone group also facilitates the formation of a range of reduction substrates, and its ready removal provides a route to enantiomerically enriched alcohols that would otherwise be extremely difficult to prepare by direct ATH of the corresponding ketones.     

Immobilization of chiral Rh catalyst on glass and application to asymmetric transfer hydrogenation of aryl ketones in aqueous media

A chiral catalyst, Cp＊RhTsDPEN （Cp＊ = pentamethyl cyclopentadiene, TsDPEN = substitutive phenylsulfonyl-l,2-diphenylethylenediamine）, was synthesized and immobilized at the surface of glass. The immobilized catalyst exhibited good catalytic efficiency for asymmetric transfer hydrogenation of aromatic ketones in water with HCOONa as hydrogen source.     

Enantioselective Rh-catalyzed transfer hydrogenation of α-sulfonyloxy heteroaryl ketones; asymmetric synthesis of (S)-bufuralol

Asymmetric transfer hydrogenation of α-sulfonyloxy heteroaryl ketones mediated by Cp1RhCl[(S,S)-TsDPEN] using an azeotropic mixture of formic acid/triethylamine afforded the corresponding diol-2-monosulfonates in excellent yield with high enantioselectivity. This led to the asymmetric synthesis of (S)-bufuralol.     

手性氨基酸及其衍生物配体在酮不对称氢转移反应中的应用进展

前手性酮的不对称氢转移反应(ATH)是获得手性醇的重要方法.近年来氨基酸及其衍生物在金属Ru,Rh,Ir催化酮的ATH中的应用引起人们关注.就氨基酸、氨基酸酰胺、氨基酸硫代酰胺、氨基酸羟胺酸、氨基酸酰肼、氨基醇及氨基酸羟基酰胺等为配体的金属络合物在ATH中的催化性能进行了综述.