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.     

新的钌环丙烷化催化体系的探索(Ⅱ) 氮膦配体立体化学结构控制顺反比选择性的初步研究

本文研究了一个新的钌催化的苯乙烯环丙烷化反应催化体系。当该催化体系用三氟甲磺酸银预处理后其催化的环丙烷化反应产物的顺反比接近1：1,且顺式产物略微占优。这在环丙烷化反应中是不多见的。我们用分子力学／动力学对该催化体系进行了模拟。结果表明键能并非是决定产物顺反比的主要因素,但是对于非键能来说,由于中间体M1与苯乙烯作用生成顺式产物时的范德华作用非常强,它弥补了由静电能所引起的能量上的不利因素。所以总能量对生成顺式产物较为有利。但是由于生成顺式产物与反式产物的总能量差别不大（2．5kcal.mol^-1),所以环丙烷化产物的顺反比接近1：1。这是氮膦配体立体化学结构控制产物选择性的结果。     

新型手性环状胺膦配体的设计合成及在酮的不对称还原中的应用

新型手性配体的设计合成是不对称催化研究的重要内容,其中手性胺膦配体因同时含有"软"的磷原子和"硬"的氮原子而具有丰富的配位化学性能和优秀的不对称诱导能力.本文总结了本研究组最近设计合成的手性环状胺膦配体的制备、表征及其在铁催化酮的不对称还原中的应用.手性1,2-环己二胺与双(2-甲酰基苯基)苯基膦通过[2+2]环缩合反应能够顺利获得手性22元环的亚胺膦配体21,该配体经Na BH4还原后生成大环胺膦配体22.利用手性大环胺膦配体22与Fe3(CO)12原位生成的催化体系,能够高活性、高对映选择性地实现包括杂环芳香酮在内50多种酮的不对称转移氢化和不对称氢化反应,其S/C(底物与催化剂的摩尔比)最高可达5000:1,产物手性芳香醇的光学纯度高达99%ee.     

铜化合物在合成菊酸乙酯中的催化作用

以铜化合物催化重氮乙酸乙酯与2,5-二甲基-2,4-己二烯的环丙烷化反应,得到了高活性、高选择性的催化剂。探讨了催化剂结构与环丙烷化产率的关系,发现催化剂阴离子的吸电子能力、配体与铜(Ⅰ)的配位能力以及配体的空间位阻等对环丙烷化产率的影响有一定的规律性。     

手性pybox-金属络合物及其在不对称催化反应中的应用

具有C2对称性的双噁唑啉型吡啶(pybox)是一类有效的手性配体,能与许多金属离子配位,其手性催化性能已得到越来越多的关注。本文综述了手性配体pybox和pybox-金属络合物的合成方法,特别是近年来pybox-金属络合物在不对称催化反应如不对称环丙烷化反应、不对称Diels-Alder反应、1,3-偶极环加成反应、不对称aldol反应等中应用的最新进展。     

钯催化不对称氢化研究

<正>催化均相不对称氢化是有机化学的前沿研究领域之一,其催化体系主要是钌、铑和铱等手性催化剂,而钯应用于均相不对称氢化中的例子很少报道,其主要原因可能是钯的配位数较低和容易生成有催化活性的钯黑所致。我们认为如果使用含有弱配位阴离子的钯前体和对钯具有较好稳定作用的手性配体和溶剂,就可能会实现钯的均相不对称氢化新体系。     

手性双(口恶)唑啉配体-金属配合物在催化不对称环丙烷化反应中的应用研究进展

将用于催化不对称环丙烷化反应中的手性双(口恶)唑啉配体按相应羧酸母体骨架分为丙二酸类,酒石酸类,吡啶二羧酸类,联苯、联萘及双核二茂铁类,将聚合物支载的双(口恶)唑啉配体单独进行了讨论.对各类配体的最新研究进展及其金属配合物在不对称环丙烷化反应中的应用作了总结.     

亮点介绍

<正>铱催化具有环外双键的α,β-不饱和环酮的不对称氢化J.Am.Chem.Soc.2010,132,4538～4539手性烯丙醇是一类非常重要的有机合成中间体,在手性药物和天然产物的合成中有着广泛的应用.α,β-不饱烯酮的不对称催化氢化反应是制备手性烯丙醇化合物的最直接方法.然而,目前成功的例子仅限于钌-双膦/双胺络合物     

吡啶基桥联双四唑钌(Ⅱ)配合物催化酮的转移氢化反应（英文）

含氮配体具有稳定性好、易于合成等优点,而且其过渡金属配合物表现出较高的催化活性,因而在配位化学和均相催化等研究领域受到了广泛关注.基于吡啶骨架的三齿NNN配体具有良好的配位能力和丰富的配位模式,如吡啶桥联的对称配体2,2':6',2'-三吡啶、2,6-双噁唑啉基吡啶、2,6-双亚胺基吡啶和2,6-双吡唑基吡啶等在有机合成及配合物催化剂制备等方面得到广泛应用.2,6-双四唑基吡啶也是基于吡啶的多齿配体,已被用于合成发光材料或高效回收次锕系元素等,但是其在催化领域的应用较少.过渡金属催化的不饱和化合物的转移氢化反应具有反应条件温和、不直接使用氢气等优点,因而受到越来越多的关注.一系列优异的配体及配合物在转移氢化反应中脱颖而出,如对甲苯磺酰手性二胺配体、2-甲胺基吡啶钌配合物、配体中含有NH官能团的过渡金属配合物等.我们也报道了几种吡啶基桥联的含氮配体及其钌配合物,并应用于催化酮的转移氢化反应.在此基础上,本文合成了三种连有不同膦配体的2,6-双四唑基吡啶钌配合物,并用于催化酮的转移氢化反应.从N~2,N~6-二对甲苯基-2,6-吡啶二甲酰胺(1)出发,经氯代/环化两步反应合成4-氯吡啶基桥联双四唑化合物(2),配体2与RuCl_2(PPh_3)_3在对应的反应条件下制得三种连有不同膦配体的2,6-双四唑基吡啶钌配合物(3),其分子结构通过核磁共振波谱和X射线单晶晶体结构测定得到确认.将这三种钌配合物应用于催化酮的转移氢化反应,当催化剂用量为0.5 mol%时,在异丙醇回流条件下,比较连有不同膦配体的2,6-双四唑基吡啶钌配合物的催化活性.膦配体为1,4-双(二苯基膦)丁烷的钌配合物3b表现出更高的催化活性,含有双三苯基膦的钌配合物3a则表现出与3b相当或略低的催化活性,含有1,5-双(二苯基膦)戊烷的钌配合物3c活性最差.以3b为催化剂拓展了一系列酮底物,取代的芳香酮、链状和环状的脂肪酮都可以高效地被还原,大部分酮底物以95%的转化率还原成相应的醇.含有氯取代基的苯乙酮对反应有较大的加速作用,反应时间更短,转化率更高.由于羰基环的张力,1-四氢萘酮与9-芴酮转化率略低.结合实验结果与相关文献,提出了一条基于Ru-H活性中间体的内层反应机理:钌配合物在iPrOK作用下生成Ru(Ⅱ)-烷氧基中间体Ⅰ,随后发生β-H消除反应脱去一分子丙酮得到Ru-H配合物,Ru-H配合物与酮底物作用经过渡态Ⅱ生成另一分子Ru(Ⅱ)-烷氧基中间体Ⅲ,随后异丙醇与烷氧基发生交换生成目标产物,同时生成中间体Ⅰ完成催化循环.     

手性二茂金属膦配体在不对称合成中的应用及新进展

手性二茂金属膦配体在不对称合成中的应用及新进展牟宗刚，吕士杰，周宏英，傅宏祥（中国科学院兰州化学物理研究所兰州７３００００）关键词二茂铁膦配体，烯丙基化合物，二茂钌膦配体，不对称合成，不对称催化，均相催化１前言众所周知，催化作用的研究已成为近代化学的...     

用原位变温19F NMR研究三氟甲磺酸根在苯乙烯不对称环丙烷化反应中的作用

The role of trifluoromethanesulfonate ion (OTf -) in asymmetric cyclopropanation of styrene catalyzed by ruthenium complex of chiral N, P ligand is investigated by in situ variable temperature 19 F NMR. The temperature of NMR experiment varies from 243 K to 283 K. After ethyl diazoacetate and styrene are added into the catalytic system, the process that the OTf - leaves from the central metal is observed from the change of the 19 F NMR spectra. Owing to the weakly coordinating behavior, trifluoromethanesulfonate ion can be easily removed from the central metal and replaced by substrates to form the reactive intermediate during the reaction. So that the catalytic reactivity can be improved greatly when the silver trifluoromethanesulfonate is added to the catalytic system.     

Highly hydrated cations: deficiency, mobility, and coordination of water in crystalline nonahydrated scandium(III), yttrium(III), and lanthanoid(III) trifluoromethanesulfonates

Trivalent lanthanide-like metal ions coordinate nine water oxygen atoms, which form a tricapped trigonal prism in a large number of crystalline hydrates. Water deficiency, randomly distributed over the capping positions, was found for the smallest metal ions in the isomorphous nonahydrated trifluoromethanesulfonates, [M(H2O)n](CF3SO3)3, in which M = Sc(III), Lu(III), Yb(III), Tm(III) or Er(III). The hydration number n increases (n = 8.0(1), 8.4(1), 8.7(1), 8.8(1) and 8.96(5), respectively) with increasing ionic size. Deuterium (2H) solid-state NMR spectroscopy revealed fast positional exchange between the coordinated capping and prism water molecules; this exchange started at temperatures higher than about 280 K for lutetium(III) and below 268 K for scandium(III). Similar positional exchange for the fully nonahydrated yttrium(III) and lanthanum(III) compounds started at higher temperatures, over about 330 and 360 K, respectively. An exchange mechanism is proposed that can exchange equatorial and capping water molecules within the restrictions of the crystal lattice, even for fully hydrated lanthanoid(III) ions. Phase transitions occurred for all the water-deficient compounds at approximately 185 K. The hydrated scandium(III) trifluoromethanesulfonate transforms reversibly (DeltaH degrees = -0.80(1) kJ mol(-1) on cooling) to a trigonal unit cell that is almost nine times larger, with the scandium ion surrounded by seven fully occupied and two partly occupied oxygen atom positions in a distorted capped trigonal prism. The hydrogen bonding to the trifluoromethanesulfonate anions stabilises the trigonal prism of water ligands, even for the crowded hydration sphere of the smallest metal ions in the series. Implications for the Lewis acid catalytic activity of the hydrated scandium(III) and lanthanoid(III) trifluoromethanesulfonates for organic syntheses performed in aqueous media are discussed.     

Structural insights into aluminum chlorofluoride (ACF)

The structure of the very strong solid Lewis acid aluminum chlorofluoride (ACF, AlCl(x)F(3-x), x = 0.05-0.3) was studied by IR, ESR, Cl K XANES, (19)F MAS NMR, and (27)Al SATRAS NMR spectroscopic methods and compared with amorphous aluminum fluoride conventionally prepared by dehydration of alpha-AlF(3) x 3H(2)O. The thermal behavior of both compounds was investigated by DTA and XRD. In comparison to ACF, amorphous AlF(3) prepared in a conventional way is not catalytically active for the isomerization reaction of 1,2-dibromohexafluoropropane, which requires a very strong Lewis acid. Both compounds are mainly built up of corner-sharing AlF(6) octahedra forming a random network. The degree of disorder in ACF is higher than in amorphous AlF(3). Terminal fluorine atoms were detected in ACF by (19)F NMR. The chlorine in ACF does not exist as a separate, crystalline AlCl(3) phase. Additionally, chlorine-containing radicals, remaining from the synthesis, are trapped in cavities of ACF. These radicals are stable at room temperature but do not take part in the catalytic reaction.     

Copper-63 NMR line width study of the copper(I)-acetonitrile system

The principal focus of this study is the (63)Cu NMR line widths in Cu(I)-acetonitrile (AN) solutions. The variations with the concentrations of Cu(I) salts (trifluoromethanesulfonate and perchlorate), added salts, water, chloride ion, and temperature have been studied. A quantitative analysis shows that the anomalous temperature dependence of the line widths is not due to ion pairing or anion complexation but results primarily from formation of a species with a different coordination number or less symmetrical arrangement of AN ligands than in the normal tetrahedral Cu(AN)(4)(+) ion. Solvent viscosity and ion pairing (with triflate) also are identified as factors having the expected effects on the line widths. The results of earlier studies also are discussed and analyzed by the current model where possible.     

NMR and impedance spectroscopy data on the ionic mobility and conductivity in PbSnF4 doped with alkali metal fluoride

NMR and impedance spectroscopy are used to study the ionic mobility and conductivity in crystalline samples in PbSnF₄-MF systems (M = Li, Na, K) in a 150?C473 K temperature range. The ¹⁹F NMR spectral parameters, types of ionic motion, and ionic conductivity value in the PbSnF₄ compound doped with alkali metal fluoride is found to be determined by the temperature, nature, and concentration of an alkali cation. The specific conductivity of the crystalline samples in PbSnF₄-MF systems (M = Li, Na, K) is rather high at room temperature and hence, it seems possible to apply them in the development of functional materials with high ionic (superionic) conductivity.     

Calix[6] arene—bismetalloporphyrins as Enzyme Models for P450 V.Catalytic Performance in Epoxidation of Styrene

In this paper the catalytic performance of the calix[6]arene-bismetalloporphyrins in the epoxidation of styrene was studied.The influence of phase transfer catalyst,pH value,buffer agent,substrate concentration,substituent on the benzene ring of porphyrin,and the central metal ion,etc.,on the reaction rates were investigated meticulously.The results showed that the calix[6] arene-bismetalloporphyrins had a much higher catalytic activity than that of the corresponding metalloporphyrins.     

On the preparation of fluorine-18 labelled XeF(2) and chemical exchange between fluoride ion and XeF(2)

A recent report claims to have prepared [18F]XeF2 by exchange between a large stoichiometric excess of XeF2 and no-carrier-added 18F-, as salts of the [2,2,2-crypt-M+] (M = K or Cs) cations, in CH2Cl2 or CHCl3 solvents at room temperature. Attempts to repeat this work have proven unsuccessful and have led to a critical reinvestigation of chemical exchange between fluoride ion, in the form of anhydrous [N(CH3)4][F] and [2,2,2-crypt-K][F], and XeF2 in dry CH2Cl2 and CH3CN solvents. It was shown, by use of 19F and 1H NMR spectroscopies, that [2,2,2-crypt-K][F] rapidly reacts with CH3CN solvent to form HF2-, and with CH2Cl2 solvent to form HF2-, CH2ClF, and CH2F2 at room temperature. Moreover, XeF2 rapidly oxidizes 2,2,2-crypt in CH2Cl2 solvent at room temperature to form HF and HF2-. Thus, the exchange between XeF2 and no-carrier-added 18F- reported in the prior work arises from exchange between XeF2 and HF/HF2-, and does not involve fluoride ion. However, naked fluoride ion has been shown to undergo exchange with XeF2 under rigorously anhydrous and HF-free conditions. A two-dimensional 19F-19F EXSY NMR study demonstrated that [N(CH3)4][F] exchanges with XeF2 in CH3CN solvent, but exchange of HF2- with either XeF2 or F- is not detectable under these conditions. The exchange between XeF2 and F- is postulated to proceed by the formation of XeF3- as the exchange intermediate.     

Mechanistic studies on the catalytic cycle of metal fluoride-catalyzed allylation using allyltrimethoxysilane in protic solvents

The catalytic cycles of CdF(2).1-catalyzed and AgF.BINAP-catalyzed allylation using allyltrimethoxysilane in protic solvents were investigated. The experimental and (19)F NMR studies strongly supported that metal fluorides were regenerated from silyl fluoride species, and that these reactions were truly fluoride-catalyzed reactions. It was revealed that these catalytic cycles were much different from that of TBAF-catalyzed allylation using allyltrimethylsilane in THF.     

Radical polymerization of metal-coordinated monomers with ligands of pyrrole-containing schiff bases

The copper complexes and the cobalt complex with the ligand of 3-(2-pyrrolylmethyl-enimino)propene-1 (PIP) or p-(2-pyrrolylmethylenimino)styrene (PIS) were synthesized and homopolymerizations and the copolymerization with styrene, acrylonitrile, methyl methacrylate and acrylic acid studied. In the polymerization of chelate monomers, inhibition of radical polymerization by the central metal ion was observed, but the chelate polymer could be obtained only if the initiator was present in higher concentrations in the feed. It is considered that the strength of inhibition depends on the electronic configuration of d-orbitals of the central metal ion. The initiation mechanism of the cupric chelate monomer may be reduction of the metal ion by the redox reaction with a primary radical via the intramolecular electron transfer through the π-conjugated system of the ligand prior to the propagation step. This mechanism was verified by studying the redox reaction of various copper complexes with DPPH. In the system of the copper complex containing PIS and acylic acid the alternating copolymer could be obtained at any mole fraction of monomer mixture in feed.     

PNPP catalytic hydrolysis by mono- and binuclear transition-metal complexes with polyether-bridged dihydroxamic acids

Polyether-bridged dihydroxamic acids and their mono- and binuclear copper(II), and cobalt(II) complexes have been synthesized and employed as models to mimic hydrolase in the catalytic hydrolysis of p-nitrophenyl picolinate (PNPP). The kinetics and the mechanism of PNPP hydrolysis have been investigated. The kinetic mathematical model of PNPP cleavage by the complexes has been proposed. The effects of the different central metal ion, mono- and binuclear metal, the pseudo-macrocyclic polyether constructed by the polyethoxy group in complexes, and reactive temperature on the rate of PNPP catalytic hydrolysis have been examined. The results show that the transition-metal dihydroxamates exhibit high catalytic activity in the PNPP hydrolysis; the rate of the PNPP hydrolysis increases with the increase in pH of the buffer solution; the catalytic activity of binuclear complexes is higher than that of mononuclear complexes; the catalytic activity of copper(II) complex is about four times that of the cobalt(II) complex; the pseudo-macrocyclic polyether can synergetically activate H₂O coordinated to the metal ion with the central metal ion together and promote the PNPP catalytic hydrolysis.