水/有机两相体系中钌膦配合物催化苯乙酮及其衍生物的不对称加氢反应

 将手性二胺(1S,2S)-1,2-二苯基乙二胺二磺酸钠((1S,2S)-DPENDS)修饰的钌膦配合物用于催化水/有机两相体系中苯乙酮的不对称加氢. 结果表明, (1S,2S)-DPENDS和KOH的浓度对反应有很大影响,二者的协同作用使配合物的催化活性和产物的对映选择性大大提高. 对温度、压力、底物/钌的摩尔比和膦配体/钌摩尔比等反应条件进行优化后,以［RuCl2-(TPPTS)2］2为催化剂前体催化苯乙酮不对称加氢时,产物的ee值可达66.4%, 催化剂经过简单的相分离即可循环使用.     

聚乙二醇-水介质中水溶性膦稳定的钌催化芳香酮的不对称加氢反应

在聚乙二醇-400-水介质中,以(1S,2S)-1,2-二苯基乙二胺的磺酸钠盐为手性修饰剂,考察了水溶性三(间-磺酸钠苯基)膦稳定的Ru催化苯乙酮及其衍生物的不对称加氢反应.结果表明,该催化剂体系具有良好的催化活性和对映选择性.在优化反应条件下,苯乙酮转化率和对映选择性分别为100％和84.9％.经正己烷萃取后,催化剂...     

(1S,2S)-1,2-二苯基乙二胺修饰Ir/HAP催化苯乙酮及其衍生物的不对称加氢反应

采用浸渍法在温和条件下制备了羟基磷灰石负载的铱催化剂(Ir/HAP), 并以X射线衍射(XRD), 透射电子显微镜(TEM), X射线光电子能谱(XPS), 比表面积测定(BET)以及附带能量散射X射线谱的扫描电子显微镜(SEM-EDS)等手段对载体和催化剂进行了表征. 以(1S,2S)-1,2-二苯基乙二胺((1S,2S)-DPEN)为手性修饰剂时, 该催化剂对苯乙酮及其衍生物不对称加氢反应表现出较高活性和对映选择性(ee). 在氢气压力为3.0 MPa、303 K条件下反应3 h, 苯乙酮及其衍生物的加氢转化率在94.7%以上, 其中生成2'-(三氟甲基)苯乙醇的对映选择性高达81.5%. 在不使用其它配体作稳定剂的情况下, 该结果比目前文献报道值高. 通过对比研究发现, 羟基磷灰石作为载体优于二氧化硅等其它无机载体. 催化剂通过简单离心分离可循环使用多次, 无明显的金属铱流失.     

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.     

(1S,2S)-1,2-二苯基乙二胺修饰Ir/SiO_2催化苯乙酮及其衍生物不对称加氢(英文)

不添加任何稳定剂,在碱性条件下制备了5%Ir/SiO2催化剂,并用于催化苯乙酮的不对称加氢反应中,详细考察了碱和手性修饰剂种类、氢气压力、反应温度、(1S,2S)-1,2-二苯基乙二胺((1S,2S)-DPEN)浓度对反应的影响.在优化反应条件下,5%Ir/SiO2催化剂表现出较好的反应活性和对映选择性.其中,苯乙酮不对称加氢反应的对映选择性达70%.该催化剂不需要任何稳定剂,制备方法简单,催化性能稳定,通过简单的离心分离即可循环使用.     

L-脯氨酸稳定的铱催化苯乙酮及其衍生物不对称加氢反应

以L-脯氨酸为稳定剂制备了负载型金属铱催化剂, 并用于苯乙酮及其衍生物不对称加氢反应. 考察了载体以及L-脯氨酸的量对催化剂性能的影响, 以透射电镜(TEM)和X射线光电子能谱(XPS)对催化剂进行了表征. 结果表明L-脯氨酸对金属铱粒子具有较好的分散和稳定作用. 通过考察反应条件发现: 碱金属离子对反应有较大影响; L-脯氨酸与手性修饰剂对催化活性和对映选择性存在一定的协同促进作用. 在手性二胺(1S,2S)-1,2- 二苯基乙二胺 ((1S,2S)-DPEN) 修饰下, 催化剂 5% (w, 质量分数)Ir/15( 脯氨酸与铱的摩尔比)(L-Proline)-γ-Al2O3催化苯乙酮不对称加氢获得了71.3%的对映选择性(ee), 2?-(三氟甲基)苯乙醇的对映选择性达到了79.8%. 该催化剂制备方法简单, 不需要膦配体做稳定剂, 催化剂性能稳定, 通过简单的离心分离可循环使用5次而无明显的活性和对映选择性降低.     

(1S,2S)-1,2-二苯基乙二胺修饰Ir/SiO2催化苯乙酮及其衍生物不对称加氢（英文）

不添加任何稳定剂,在碱性条件下制备了5%Ir/SiO2催化剂,并用于催化苯乙酮的不对称加氢反应中,详细考察了碱和手性修饰剂种类、氢气压力、反应温度、(1S,2S)-1,2-二苯基乙二胺((1S,2S)-DPEN)浓度对反应的影响.在优化反应条件下,5%Ir/SiO2催化剂表现出较好的反应活性和对映选择性.其中,苯乙酮不对称加氢反应的对映选择性达70%.该催化剂不需要任何稳定剂,制备方法简单,催化性能稳定,通过简单的离心分离即可循环使用.     

水相中RuCl2(TPPTS)2-(S,S)-DPENDS催化苄叉丙酮的不对称加氢反应

 将水溶性手性二胺 (S,S)-1,2-二苯基乙二胺二磺酸钠 ((S,S)-DPENDS) 与钌膦配合物 ([RuCl2(TPPTS)2]2) 原位生成的催化剂用于催化水相中苄叉丙酮的不对称加氢反应. 在优化条件下, 羰基加氢产物 4-苯基-3-丁烯-2-醇的选择性可达 96.0%, 对映选择性可达 71.2%. 经正己烷简单萃取后即可实现催化剂与加氢产物的分离, 循环使用 5 次后, 目标产物 4-苯基-3-丁烯-2-醇选择性和对映选择性没有明显下降.     

手性二胺修饰的镍配合物催化苯乙酮及其衍生物的不对称加氢反应

本文研究了由手性修饰剂(S,S)D-DPEN(DPEN:1,2一二苯基乙二胺)在反应条件下与NiCl2(PPh3)2原位生成的手性催化剂对苯乙酮及其衍生物不对称加氢反应的催化性能,考察了反应温度、反应压力、(S,S)-DPEN浓度等变化因素对催化活性和对映选择性的影响。结果表明,在15℃,氢气压力为8.0MPa,乙醇作溶剂时,苯乙酮加氢产物(R)-苯乙醇的对映选择性达到了77.2%e.e。     

手性双二茂铁基配体的合成、表征及固体CD光谱

以甲酰基二茂铁(1)和手性1,2-二苯基乙二胺[(1R, 2R)-1,2-二苯基乙二胺(2R), (1S,2S)-1,2-二苯基乙二胺(2S)]为原料, 经缩合、还原和N-烷基化反应, 制备了一对新型手性四齿双二茂铁基配体[N,N’-二(二茂铁基甲基)-N,N’-二(2-羟基丙基)-(1R,2R)-1,2-二苯基乙二胺(5R)和N,N’-二(二茂铁基甲基)-N,N’-二(2-羟基丙基)-(1S,2S)-1,2-二苯基乙二胺(5S)]. 用元素分析、红外(IR)、质子核磁共振(1H NMR)、紫外-可见(UV-Vis)、固体圆二色(CD)光谱等对手性产物(3R-5S)进行了表征. 固体CD光谱研究表明, 配体5R(或5S)的手性特征和4R(或4S)相似而与3R(或3S)却有一定差别.     

(1S, 2S)-DPEN修饰的负载型钌-铑双金属催化剂催化苯乙酮及其衍生物的不对称加氢

制备了以三苯基膦(PPh3)作为助剂的Ru-Rh/γ-Al2O3 催化剂, 在氢氧化钾的异丙醇溶液中, 用(1S, 2S)-DPEN [(1S, 2S)-1,2-diphenylethane-1,2-diamine]作手性修饰剂对苯乙酮及其衍生物进行不对称催化加氢, 此催化剂表现出较高的催化活性和良好的对映选择性. 优化反应条件, 苯乙酮、乙基苯基酮和异丙基苯基酮的转化率分别达到92.5%, 95.9%, 100%, 生成(R)-构型产物的ee值分别达到79.6%、81.2%和81.4%.     

Asymmetric Hydrogenations of Acetophenone and Its Derivatives over RuRh/γ-Al2O3 Modified by (1S,2S)-DPEN and PPh3

The asymmetric hydrogenations of acetophenone and its derivatives over the bimetallic catalyst RuRh/γ-Al₂O₃ modified by PPh3 and (1S, 2S)-DPEN [(1S, 2S)-1,2-diphenylethylene-1,2-diamine] were studied. The effects of the concentration of KOH, temperature, ratio of ruthenium to rhodium, and the concentration of diamine on the asymmetric hydrogenation of acetophenone were investigated in detail. The results showed that this catalyst system had high activity and moderate enantioselectivity for the asymmetric hydrogenations of acetophenone and its derivatives. Under the optimum conditions, the conversions of acetophenone, ethylphenylketone, and isopropylphenylketone were up to 92.5%, 95.9%, and 100%, and the enantioselectivities for the formation of (R)-aromatic alcohols were 79.6%, 81.2%, and 81.4%, respectively.     

Ru-BDPX-DPEN催化芳香酮的不对称氢化反应

设计合成了一种新型的钌-双膦-手性二胺三元配合物RuC l2(BDPX)[(S,S)-DPEN][BDPX=邻-二(二苯基膦)甲苯,DPEN=1,2-二苯基乙二胺].利用此配合物作催化剂催化了苯乙酮和几种取代苯乙酮的不对称氢化反应;考察了多种因素对苯乙酮不对称氢化反应的转化率和ee值的影响.结果表明,此配合物对苯乙酮进行不对称氢化反应具有良好的催化性能和较高的对映选择性,在优化的条件下,当苯乙酮、配合物的摩尔比为20000?1时,其不对称氢化反应的转化率可达到100%,其ee值可达到59.0%;对取代苯乙酮的不对称氢化反应也具有一定的催化活性和中等的对映选择性.     

Sn-promoting mechanism for ketone hydrogenation over Rh/SiO2

Hydrogenation of acetophenone, 2-butanone, styrene and 1-hexene over Rh---Sn/SiO₂ in heterogeneous liquid phase reaction systems was studied by in situ EXAFS, FT-IR, TEM, analytical TEM, CO and H₂ adsorption measurements. The catalytic activity of Rh/SiO₂ for hydrogenation of acetophenone and 2-butanone increased by a factor of 5–500 by Sn addition, showing a maximum activity at surface composition Sn_s/Rh_s = 1.5, whereas hydrogenation of styrene and 1-hexene decreased monotonously and drastically by Sn addition. In situ Sn K-edge EXAFS of the well characterized CVD-Rh---Sn/SiO₂ catalyst prepared by using Sn(CH₃)₄ vapor suggested that oxygen of C=O group makes a bond with Sn atom upon acetophenone adsorption.     

PEG-400-H2O as a green and recyclable medium for asymmetric hydrogenations of aromatic ketones catalyzed by RuCl2(TPPTS)2-(S,S)-DPENDS

PEG-400-H₂O was found to be a green and recyclable reaction medium for asymmetric hydrogenations of aromatic ketones catalyzed by a ruthenium achiral monophosphine complex RuCl₂(TPPTS)₂ [TPPTS: P(m-C₆H₄SO₃Na)₃] modified by (S,S)-DPENDS [disodium salt of sulfonated (S,S)-1,2-diphenyl-1,2-ethylene-diamine]. The acetophenone product was obtained with 86.3% ee under the optimized conditions. The resulting products can be easily separated from the catalyst by extraction with n-hexane. The catalyst immobilized in PEG-400-H₂O not only exhibits excellent activity and enantioselectivity, but also can be recycled and reused several times without a loss of activity or enantioselectivity.     

Computational study of the factors controlling enantioselectivity in ruthenium(II) hydrogenation catalysts

The reduction of prochiral ketones catalyzed by Ru(diphosphine)(diamine) complexes has been studied at the DFT-PBE level of theory. Calculations have been conducted on real size systems [trans-Ru(H)2(S, S-dpen)(S-xylbinap) + acetophenone], [trans-Ru(H)2(S, S-dpen)(S-tolbinap) + acetophenone] and [trans-Ru(H)2(S, S-dpen)(S-xylbinap) + cyclohexyl methyl ketone] with the aim of identifying the factors controlling the enantioselectivity in Ru(diphosphine)(diamine) catalysts. The high enantiomeric excess (99%) in the hydrogenation of acetophenone catalyzed by trans-Ru(H)2(S, S-dpen)(S-xylbinap) has been explained in terms of the existence of a stable intermediate along the reaction pathway associated with the (R)-alcohol. The formation of this intermediate is hindered with the competitive pathways, which consequently increases the activation energy for the hydrogen transfer acetophenone/(S)-phenylethanol reaction. For the [trans-Ru(H)2(S, S-dpen)(S-tolbinap) + acetophenone] system, the lower enantioselectivity (i.e. 80%) is rationalized by the smaller differences in the activation energy between the competitive pathways which differentiate between the two diastereomeric approaches of the prochiral ketone. The DFT-PBE results suggest that this reaction is driven to the (R)-product only by the process of binding the acetophenone to the active site of the trans-Ru(H) 2(S, S-dpen)(S-tolbinap) catalyst. For the hydrogenation of cyclohexyl methyl ketone catalyzed by trans-Ru(H)2(S, S-dpen)(S-xylbinap), the low performance in the enantioselective hydrogenation of the dialkyl ketone (i.e. 37%) is again explained by the small differences in the activation and binding energies which are the factors which could effectively differentiate between the two alkyl groups.