新型可回收高聚物负载手性配体在苯乙烯类化合物均相不对称双羟化反应中的催化性能研究

在多聚磷酸和AlCl3存在下，邻苯二甲酸酐与对二氟苯中通过Friedel-Crafts反应环化，以60％的产率生成1，4-二氟蒽醌．在碱性条件下，聚乙二醇单甲醚(HO-OPEG-OMe)与1，4-二氟蒽醌进行亲核单取代反应生成中间体F-AQN-OPEG-OMe，产率88％．然后F-AQN-OPEG-OMe与奎尼丁的锂盐再进行亲核取代反应，以91．7％的产率得到新型手性配体QD-AQN-OPEG-OMe．QD-AQN-OPEG-OMe与OsO4原位配位生成的均相催化剂在4种苯乙烯类化合物的不对称双羟化反应中表现出高的立体选择性(80％～94％ee)和催化活性(产率88％～96％)．催化活性和立体选择性与Sharpless手性配体(DHQD)2AQN相当．反应结束后，加入乙醚可使配体沉淀和回收，配体的回收率均在95％～97％之间．循环使用5次，催化剂的催化活性和立体选择性无明显改变．     

新手性配体(QN)2AQN的合成及其催化肉桂酸甲酯的不对称氨羟化反应研究

在AlCl₃和多聚磷酸的存在下, 以邻苯二甲酸酐和对二氟苯为原料, 通过Friedel-Crafts和环化反应, 用改进的方法以60%的产率生成1,4-二氟蒽醌. 然后通过奎宁锂与1,4-二氟蒽醌的亲核取代反应得到新型手性配体(QN)₂AQN, 产率85%. 在氧化-供氮试剂N-氯代氨基甲酸苄酯存在下, (QN)₂AQN与OsO₄原位生成的催化剂在五种肉桂酸甲酯的不对称氨羟化反应中表现出优异的对映选择性(90%～96% ee)和一般至优秀的区域选择性(75∶25～98∶2), 产率50%～70%, 高于文献报道的结果. 该手性配体易于合成, 成本低廉, 用于催化不对称氨羟化反应, 可以制备光学活性的α-氨基酸酯类化合物.     

手性配体3,6-双(9-O-二氢奎尼丁)哒嗪的合成及其在烯烃不对称氨羟化反应中的催化性能

 采用改进的方法,以NaH作为碱,在温和条件下通过二氢奎尼丁和3,6-二氯哒嗪的亲核取代反应合成了手性配体3,6-双(9-O-二氢奎尼丁)哒嗪((DHQD)2PYDZ), 配体的产率为78%. 以N-氯代氨基甲酸苄酯钠为氧化-供氮试剂,由(DHQD)2PYDZ与OsO4原位生成的催化剂在6种烯烃的不对称氨羟化反应中表现出较高的立体选择性(83%～92%)和区域选择性(79:21～88:12),反应主产物的化学产率为40%～76%.     

α,β-丙烯酸酯立体选择性环氧化

以D-(-)-果糖为手性源,经过丙酮保护、氧化、选择性脱保护、三氟酰化四步反应得到手性酮4。以手性酮4为催化剂,立体选择性环氧化α,β-丙烯酸酯,较高产率和立体选择性地获得了重要的手性中间体α,β-环氧丙酸酯。产率和e.e.值分别达到76%~92%和92%~98%。     

新型手性双膦配体的合成及其催化性能考察

以苯乙烯为原料,通过Sharpless不对称二羟基化反应合成高对映体纯的苯基乙二醇,经环化、亲核开环和取代反应转化为手性碳膦-氧膦型双膦配体.后者与[Rh(COD)Cl]2及NH4PF6作用生成手性膦-铑阳离子催化剂.在α-脱氢氨基酸衍生物的不对称氢化反应中,化学转化率为100%,对映选择性最高达到77?.     

1,4-二烯和醛的烯丙基碳氢不对称烷基化反应

利用钯配合物、有机胺和手性布朗斯特酸三元催化剂体系实现了α-取代丙醛参与的1,4-二烯烃的烯丙基碳氢不对称烷基化反应,以良好的产率、优良的区域选择性和立体选择性得到了结构多样的手性α-羰基化合物.此外发现非手性膦配体对钯配合物的催化活性和反应的选择性有十分显著的影响,为后续相关研究提供了新的思路.     

SDP配体在铑催化的Pauson-Khand反应中的应用

研究了SDP作为双膦配体与金属铑形成的手性催化剂在不对称Pauson-Khand反应中的催化活性和对映选择性, 并考察了影响反应活性和对映选择性的各种因素. 结果表明, SDP配体对铑催化的Pauson-Khand反应是一种有效的手性配体, 它与铑生成的手性催化剂能在1大气压的一氧化碳气氛中, 将一系列1,6-烯炔化合物转化为相应的双环戊烯酮, 反应的对映选择性较高. 在SDP配体中苯环上引入取代基导致反应的对映选择性降低, 但是当取代基为甲氧基时, 催化剂的活性得到明显提高. 溶剂实验表明1,2-二氯乙烷是理想的反应溶剂. 催化剂的阴离子对催化剂活性和对映选择性也有十分重要的影响, 采用六氟锑酸根时, 反应的对映选择性最高.     

一种可回收手性配体的合成及其对烯烃不对称二羟化反应的催化性能

 用1,4-二氟蒽醌与奎宁(QN)反应可高收率地得到1,4-双-(9-O-奎宁)蒽醌((QN)2AQN),再经OsO4氧化可得到带有4个羟基的手性配体. 在不对称二羟化反应的2种不同体系中,该配体对6种烯烃的反应表现出很高的对映选择性(80%～97%)和催化活性(80%～94%). 该配体不但具有金鸡纳生物碱衍生物小分子配体优异的立体选择性,同时也能象高聚物负载的大分子配体一样能够回收和重复使用,而且用量少,活性高,后处理简单. 在以反式肉桂酸乙酯为底物的不对称二羟化反应中,在t-BuOH-H2O/K3Fe(CN)6体系中循环使用5次(配体平均回收率93%),在Me2CO-H2O/NMO(N-甲基-N-氧吗啉)体系中循环使用8次,配体的催化活性和对映选择性基本保持不变.     

手性噻唑烷-铑(I)配合物催化的苯乙酮不对称硅氢化反应

由L-半胱氨酸甲酯与α-吡啶甲醛缩合制备了2-(α-吡啶基)-4-羧甲基-1, 3-噻唑烷手性配体。用该手性配体与[Rh(COD)]2反应原位生成的Rh(I)配合物为催化剂进行了苯乙酮的不对称硅氢化反应。反应的化学产率达91%, 光学产率达82.1%e.e.。考察了各种反应条件对催化剂性能的影响。     

新型手性膦-硼烷配合物的合成及其在不对称催化氢化反应中的应用

以苯乙烯为原料,通过Sharpless不对称二羟基化反应合成高对映体纯的苯基乙二醇,经酯化、亲核取代反应转化为手性膦-硼烷配合物.后者克服了有机膦配体易氧化的缺点,其制备过程简单,易于提纯,在空气中可长期保存.该手性膦-硼烷配合物在四氟硼酸-甲醚的存在下解络,生成的自由膦不经分离直接与[Rh(COD)Cl]₂作用生成手性膦-铑原位催化剂.在α-乙酰氨基肉桂酸甲酯的不对称氢化反应中,转化率为100%,对映选择性88%e.e.     

Polysiloxane-bound ligand accelerated catalysis: a modular approach to heterogeneous and homogeneous macromolecular asymmetric dihydroxylation ligands

Polysiloxane acts as a modular scaffold for macromolecular reagent development. Two separate components were covalently integrated into one material, one constituent provided reagent functionality, the other modulated solubility. In particular cinchona alkaloid based ligands used in the osmium tetroxide catalyzed asymmetric dihydroxylation (AD) reaction were covalently attached to commercially available polysiloxane. To enhance the reactivity of these polymeric ligands, multifunctional reagents were designed to include both the cinchona alkaloid and an alkoxyethylester solubilizing moiety providing random co-polymers. While the mono-functional materials led to heterogeneous conditions, the bi-functional polymers resulted in homogeneous reaction mixtures. Although both reagent types provided diol products with excellent yield and selectivity (>99% ee in nearly quantitative yield) the homogeneous analog has nearly twice the reactivity. Every repeat unit in the heterogeneous material was functionalized along the polysiloxane backbone while approximately half of these sites contained ligand in the homogeneous version. This approach led to macromolecular catalysts with high loadings of ligand and therefore materials with very low equivalent weights. Although these polymers are highly loaded they do maintain reactivity on a par with their free ligand counterpart. Using straightforward purification techniques (i.e. precipitation, simple filtration, or ultrafiltration) these polymeric ligands were easily separated from diol product and reused multiple times. Polysiloxane is a viable support for the catalysis of AD reactions and may provide a generally useful backbone for other catalytic systems.     

A trifunctional catalyst for one-pot synthesis of chiral diols via Heck coupling-N-oxidation-asymmetric dihydroxylation: application for the synthesis of diltiazem and taxol side chain

A heterogeneous bifunctional catalyst composed of OsO4(2-)-WO4(2-) and a trifunctional catalyst comprising PdCl4(2-)-OsO4(2-)-WO4(2-), designed and prepared by an ion-exchange technique using layered double hydroxides (LDH) as an ion-exchanger and their homogeneous bifunctional analogue, K2OsO4-Na2WO4 and trifunctional analogue, Na2PdCl4-K2OsO4-Na2WO4, devised for the first time are evaluated for the synthesis of chiral vicinal diols. These bifunctional and trifunctional catalysts perform asymmetric dihydroxylation-N-oxidation and Heck-asymmetric dihydroxylation-N-oxidation, respectively, in the presence of Sharpless chiral ligand, (DHQD)2PHAL in a single pot using H2O2 as a terminal oxidant to provide N-methylmorpholine oxide (NMO) in situ by the oxidation of N-methylmorpholine (NMM). The heterogeneous bifunctional catalyst supported on LDH (LDH-OsW) displays superior activity to afford diols with higher yields over the other heterogeneous catalysts developed by the ion exchange on quaternary ammonium salts covalently bound to resin (resin-OsW) and silica (silica-OsW) or homogeneous catalysts in the achiral dihydroxylation reactions. The LDH-OsW and its homogeneous analogue are found to be very efficient in performing a simultaneous asymmetric dihydroxylation (AD)-N-oxidation of a wide and varied range of aromatic, cyclic, and mono, di-, and trisubstituted olefins to obtain chiral vicinal diols with higher yields and ee's using H2O2. Further, the use of OsO4(2-)-WO4(2-) catalysts as such or in the supported form offers a simplified procedure for catalyst recycling, which shows consistent activity for a number of cycles. In this process, Os(VI) is recycled to Os(VIII) by a coupled electron transfer-mediator (ETM) system based on NMO-WO4(2-) using H2O2, leading to a mild and selective electron transfer. The one-pot biomimic synthesis of chiral diols is mediated by a recyclable trifunctional heterogeneous catalyst (LDH-PdOsW) consisting of active palladium, tungsten, and osmium species embedded in a single matrix. This protocol, which provides prochiral olefins and NMO in situ by Heck coupling and N-oxidation of NMM, respectively, required for the AD, unfolds a low cost process. We extended the present method to the one-pot synthesis of trisubstituted chiral vicinal diols with moderate to excellent ee's by AD of trisubstituted olefins that are obtained by in situ Heck arylation of disubstituted olefins. The heterogeneous trifunctional catalysts offers chiral diols with unprecedented ee's and excellent yields in the AD of prochiral cinnamates, which are obtained in situ from acrylates and halobenzenes for the first time. The new variants such as LDH support and Et3N*HX inherently composed in the heterogeneous multicomponent system and slow addition of H2O2 facilitates the hydrolysis of osmium monogylcolate ester to subdue the formation of bisglycolate ester to achieve higher ee's. Without resorting to recrystallization, the chiral diols of cinnamates thus synthesized with 99% ee's and devoid of osmium contamination are directly put to use in the synthesis of diltiazem and Taxol side chain with an overall improved yield to demonstrate the synthetic utility of the trifunctional heterogeneous catalyst. The high binding ability of the heterogeneous osmium catalyst enables the use of equimolar ratio of ligand to osmium to give excellent ee's in AD in contrast to the homogeneous osmium system in which the excess molar quantities of the expensive chiral ligand to osmium are invariably used. Further, the XRD, FT-IR, UV-vis DRS, and XPS studies indicate the retention of the coordination geometries of the specific divalent anions anchored to LDH matrix in their monomeric form during the ion exchange and after the reaction.     

A new bifunctional catalyst for tandem Heck-asymmetric dihydroxylation of olefins

A new bifunctional catalyst consisting of active palladium and osmium species anchored on silica gel through a mercaptopropyl spacer and a cinchona alkaloid respectively has been prepared for the first time and used in the heterogeneous tandem Heck-asymmetric dihydroxylation of olefins to afford diols with excellent yields and enantiomeric excesses (ee's) in presence of N-methylmorpholine N-oxide or K3Fe(CN)6 as cooxidants.     

一种可回收配体[QN(OH)2]2PYDZ在烯烃不对称双羟化及氨羟化反应中的应用

一种可重复使用的非负载型金鸡纳生物碱衍生物配体与金属锇形成原位催化剂用于9种烯烃的不对称双羟化(AD)反应, 表现了很好的对映选择性(85%～＞99%)和反应活性(82%～91%). 将其用于催化65种烯烃不对称氨羟化(AA)反应, 也表现了好的对映选择性(6176%～＞99%)和反应活性(50%～72%). 并采用两种不同的方法进行AD和AA反应中配体的回收和重复使用. 结果表明两种方法均可有效地进行配体的再利用.     

非支载可回收配体——OsO4催化烯烃的不对称氨羟化反应

非支载可回收配体——OsO4催化烯烃的不对称氨羟化反应;催化剂回收;小分子配体;不对称氨羟化反应     

用于烯烃二羟化反应的一种经济，高效且可重复使用的催化体系

以价廉的3,6-二氯哒嗪和奎宁为原料,通过两步反应即可得到一种可重复使用的金鸡纳生物碱衍生物配体。以NMO为辅助氧化剂在丙酮－水体系中，将此配体用于七种烯烃的不对称二羟化反应。反应结束后，用乙醚将产品从催化体系中萃取出来，得到80%~93%的产率和51%~99%的对映体过量值。以反式－二苯乙烯为底物进行催化体系的重复使用试验。循环使用十次，得到88%~92%的产率和>99%的对映体过量值。     

Catalytic asymmetric dihydroxylation of olefins with reusable OsO(4)(2-) on ion-exchangers: the scope and reactivity using various cooxidants

Exchanger-OsO(4) catalysts are prepared by an ion-exchange technique using layered double hydroxides and quaternary ammonium salts covalently bound to resin and silica as ion-exchangers. The ion-exchangers with different characteristics and opposite ion selectivities are specially chosen to produce the best heterogeneous catalyst that can operate using the various cooxidants in the asymmetric dihydroxylation reaction. LDH-OsO(4) catalysts composed of different compositions are evaluated for the asymmetric dihydroxylation of trans-stilbene. Resin-OsO(4) and SiO(2)-OsO(4) designed to overcome the problems associated with LDH-OsO(4) indeed show consistent activity and enantioselectivity in asymmetric dihydroxylation of olefins using K(3)Fe(CN)(6) and molecular oxygen as cooxidants. Compared to the Kobayashi heterogeneous systems, resin-OsO(4) is a very efficient catalyst for the dihydroxylation of a wide variety of aromatic, aliphatic, acyclic, cyclic, mono-, di-, and trisubstituted olefins to afford chiral vicinal diols with high yields and enantioselectivities irrespective of the cooxidant used. Resin-OsO(4) is recovered quantitatively by a simple filtration and reused for a number of cycles with consistent activity. The high binding ability of the heterogeneous osmium catalyst enables the use of an equimolar ratio of ligand to osmium to give excellent enantioselectives in asymmetric dihydroxylation in contrast to the homogeneous osmium system in which excess molar quantities of the expensive chiral ligand to osmium are invariably used. The complexation of the chiral ligand (DHQD)(2)PHAL, having very large dimension, a prerequisite to obtain higher ee, is possible only with the OsO(4)(2-) located on the surface of the supports.     

A recyclable dendritic osmium catalyst for homogeneous dihydroxylation of olefins

A series of osmate (OsO₄²⁻) core dendrimers was prepared by an ion-exchange technique through the mixing of K₂OsO₄ and a bis(quaternary ammonium bromide) core dendrimer, which consisted of poly(benzyl ether) dendron. By employing an osmate core dendrimer as a homogeneous catalyst, dihydroxylation reactions of olefins proceeded rapidly, and the dendritic osmium catalyst was recovered by reprecipitation and then reused. Furthermore, a dendritic effect on the recyclability of a catalyst was observed. In the case of asymmetric dihydroxylation reactions, the corresponding diol was obtained in a high chemical yield with a fair enantiomeric excess (ee). In this case, not only the dendritic osmium catalyst but also the chiral ligand could be recovered by reprecipitation and reused efficiently up to five times.     

Asymmetric Cyanation of Aldehydes,Ketones, Aldimines,and Ketimines Catalyzed by a Versatile Catalyst Generated from Cinchona Alkaloid,Achiral Substituted 2,2′‐Biphenol and Tetraisopropyl Titanate

Full investigation of cyanation of aldehydes, ketones, aldimines and ketimines with trimethylsilyl cyanide (TMSCN) or ethyl cyanoformate (CNCOOEt) as the cyanide source has been accomplished by employing an in situ generated catalyst from cinchona alkaloid, tetraisopropyl titanate [Ti(OiPr)₄] and an achiral modified biphenol. With TMSCN as the cyanide source, good to excellent results have been achieved for the Strecker reaction of N‐Ts (Ts=p‐toluenesulfonyl) aldimines and ketimines (up to >99 % yield and >99 % ee) as well as for the cyanation of ketones (up to 99 % yield and 98 % ee). By using CNCOOEt as the alternative cyanide source, cyanation of aldehyde was accomplished and various enantioenriched cyanohydrin carbonates were prepared in up to 99 % yield and 96 % ee. Noteworthy, CNCOOEt was successfully employed for the first time in the asymmetric Strecker reaction of aldimines and ketimines, affording various α‐amino nitriles with excellent yields and ee values (up to >99 % yield and >99 % ee). The merits of current protocol involved facile availability of ligand components, operational simplicity and mild reaction conditions, which made it convenient to prepare synthetically important chiral cyanohydrins and α‐amino nitriles. Furthermore, control experiments and NMR analyses were performed to shed light on the catalyst structure. It is indicated that all the hydroxyl groups in cinchona alkaloid and biphenol complex with Ti^IV, forming the catalyst with the structure of (biphenoxide)Ti(OR*)(OiPr). The absolute configuration adopted by biphenol 4 m in the catalyst was identified as S configuration according to the evidence from control experiments and NMR analyses. Moreover, the roles of the protonic additive (iPrOH) and the tertiary amine in the cinchona alkaloid were studied in detail, and the real cyanide reagent in the catalytic cycle was found to be hydrogen cyanide (HCN). Finally, two plausible catalytic cycles were proposed to elucidate the reaction mechanisms.