2,8-二氨基-10-羟基-5-甲基-5,10-二氢磷杂吖嗪-10-氧化物的合成及其诱变性研究

在升温条件下,二苯胺和三氯化磷反应,产物经水解、氧化得次膦酸:10-羟基-5,10-二氢磷杂吖嗪-10-氧化物(产率45%).经酰化后,与甲醇钠作用,生成相应的次膦酸甲酯.次膦酸甲酯经NaH处理后,在120℃下发生甲基迁移,形成5-甲基次膦酸(产率62%).用45倍摩尔量的硝化剂将5-甲基次膦酸硝化,得到双硝基产物(产率59%).在5%Pd/C催化下,双硝基产物又被氢气还原.考察催化剂用量对该还原反应的影响,并在最佳催化剂用量时得到2,8-二氨基-10-羟基-5-甲基-5,10-二氢磷杂吖嗪-10-氧化物(产率70%).用NMR,IR和质谱确定了所合成的5个中间体结构.对合成的氨基化合物进行Salmonella/mam-malianmicrosomeassay测试,结果表明,该氨基化合物表现为非诱变性.     

2-氨基-10-羟基-5,10-二氢磷杂吖嗪-10-氧化物的合成、诱变性及应用

2-氨基-10-羟基-5;10-二氢磷杂吖嗪-10-氧化物的合成、诱变性及应用;二氢磷杂吖嗪; 吡唑啉酮; 合成; 结构鉴定; 诱变性     

2,8-二氨基-10-甲氧基-5,10-二氢磷杂吖嗪-10-氧化物的合成、诱变性及应用性能研究

10-羟基-5，10-二氢磷杂吖嗪-10-氧化物(1)经酰氯化、甲基化得到10-甲氧基-5，10-二氢磷杂吖嗪-10-氧化物(2)，2经硝化得到10-甲氧基-2，8-二硝基，5，10-二氢磷杂吖嗪-10-氧化物(3.62％)．3在Pd／C(u=0．05)存在下，用氢气还原为2，8-二氨基-10-甲氧基-5，10-二氢磷杂吖嗪-10-氧化物(4.71％)，考察了Bd／C(w=0．05)用量对氢化还原反应的影响．经过Salmonella／mammalian microsome assay测试，4表现为非诱变性，用4与乙酰J-酸作用得到新型双偶氮酸性染料(5)．5对羊毛和丝绸分别在2％与3％色度下浸染郜得到黑色染样，考察了5的上染曲线，并对染样进行了测色研究，发现该染料属于酸性蓝黑染料，其黑度优于目前市场上流行的酸性黑10B．     

阻燃剂9,10-二氢-9-氧杂-10-膦杂菲-10-氧化物合成中酯化反应和酰基化反应的优化

有机磷杂环化合物9,10-二氢-9-氧杂-10-膦杂菲-10-氧化物(DOPO)因性能优异而作为无卤阻燃剂得到广泛应用。为了提升和改进DOPO的合成,不少文献对合成中的4个反应,即酯化反应、酰基化反应、水解反应和关环反应进行了大量研究,但是由于缺少合适的分析方法和仪器,对酯化反应和酰基化反应仍没有得出明确的结论。本文则采用了核磁共振磷谱以及测量反应产物HCl吸收碱液的温度变化两种方法,精确地得到了酯化反应和酰基化反应的优化条件。首先采用核磁共振磷谱,讨论了酯化反应温度、原料配比和加料方式对酯化反应产物组成的影响,得出了邻苯基苯氧基二氯化磷(CC)含量高的工艺条件:反应温度80℃,PCl3过量25%~50%,采用邻苯基苯酚(OPP)加入PCl3的反滴法;并得出酯化反应产物的组成直接决定了6-氯-(6氢)-二苯并-(c,e)-氧磷杂己环(CDOP)在酰基化反应产物中的含量。另通过测量HCl吸收碱液的温度变化,间接表征酰基化反应的反应速度,由此得出合适的酰基化反应温度和催化剂用量。结果为:当催化剂固定为0.2 g时,酰基化反应在150℃几乎不反应,随温度升高,反应变快,180℃下4 h完全,190℃下1.5 h即可完成;温度180℃下,1~1.5 g/1 mol OPP的催化剂较为合适,酰基化反应在3~4 h结束。     

负载型Ni催化剂高效催化2-羟基四氢吡喃还原胺化制备5-氨基-1-戊醇（英文）

伯胺等含氮化合物是最重要的化工中间体之一,被广泛应用于聚合物、医药、农药、染料和表面活性剂等产品的生产.当前,商业化伯胺主要通过卤代烃或环氧化合物直接胺化以及腈类或酰胺类化合物加氢制备,这些过程受具有特定官能团的有机原料短缺以及产生较多废物等问题的限制,导致其生产成本较高.因此,高效可持续生产伯胺化合物路径的开发得到了广泛关注.醛和酮类化合物直接与氨还原胺化反应所需温度一般较低(≤120℃),为伯胺的高选择性合成提供了一个重要途径.基于此,本文利用2-羟基四氢吡喃能够原位转化为其互变异构体5-羟基戊醛,而5-羟基戊醛中醛基具有较高还原胺化活性的特征,发展了一种以生物糠醛衍生二氢吡喃为原料,通过先水合得到2-羟基四氢吡喃再在温和条件下还原胺化合成5-氨基-1-戊醇的新方法.5-氨基-1-戊醇是一种分子中同时含有羟基和氨基的重要双官能团化合物,广泛用于医药和农药合成,也常被用作有机合成砌块,目前其主要用途是合成具有很高药用价值的生物碱Manzamine A.5-氨基-1-戊醇的一条传统合成路线是以石化基1,5-戊二醇经浓盐酸进行单氯取代制备5-氯戊醇中间体,该中间体经分离后再与氨气反应制得5-氨基-1-戊醇的方法.该方法原料成本高,产生大量废弃物,且只取得中等目标产物收率(66.6%).本文重点研究了不同氧化物载体包括SiO2,TiO2,γ-Al2O3,ZrO2和MgO负载Ni催化剂的2-羟基四氢吡喃还原胺化性能,并对比考察了CuCr2O4,雷尼Ni,Ru/C,Pd/C,Pt/C和Rh/C等商业加氢催化剂的性能.研究发现,ZrO2负载Ni催化剂的活性高于其他氧化物载体负载Ni催化剂的活性,也明显优于所对比的系列商业加氢催化剂.系列物理化学表征结果显示,Ni/ZrO2催化剂同时表现出较高的还原性和表面酸密度,这可能是该催化剂表现出最高5-氨基-1-戊醇收率的原因.以Ni/ZrO2为催化剂,于80℃,2 MPa H2条件下在间歇式反应器中催化2-羟基四氢吡喃水溶液还原胺化可取得90.8%的5-氨基-1-戊醇收率.通过固定床反应器研究了Ni/ZrO2催化剂稳定性,发现5-氨基-1-戊醇初始收率可达83%,反应90 h活性缓慢下降至初活性的81%.Ni流失和表面氧化可能是催化剂的失活的主要原因.通过对反应温度、H2压力、2-羟基四氢吡喃/NH3摩尔比等因素对反应活性调变规律的探究,推测2-羟基四氢吡喃催化还原胺化制备5-氨基-1-戊醇反应机理如下:首先,受化学平衡作用,2-羟基四氢吡喃逐渐转化为其互变异构体5-羟基戊醛;然后,5-羟基戊醛中醛基迅速与NH3反应生成亚胺中间体;最后,亚胺中间体在金属催化剂上加氢得到5-氨基-1-戊醇.     

2，3-二氯-5，6-二氰基-1，4-苯醌／NaNO2催化9，10-二氢蒽氧化脱氢

设计了一种由2,3-二氯-5,6-二氰基-1,4-苯醌（DDQ）和NaN02组成的复合催化剂,该催化剂在9,10-二氢葸氧化脱氢生成蒽的反应中表现出很高的催化活性和选择性．在120℃和1．3MPaO2下反应8h,9,10二氢蒽转化率达到99％以上,葸的选择性为99％．采用红外光谱和核磁共振方法对催化氧化脱氢的反应历程进行了研究．结果表明,9,10-二氢蒽氧气氧化脱氢生成蒽的反应是通过DDQ／DDQH2和NO2／NO两个氧化还原对的电子传递来推动的,以DDQ／NaNO2为催化剂可以有效催化9,10-二氢蒽氧化脱氢生成蒽．     

新型磷杂菲基反应型阻燃剂的合成及其在聚氨酯阻燃中的应用

以9,10-二氢-9-氧杂-10-磷杂菲-10-氧化物和1,4-丁二醇二缩水甘油醚为原料,合成了一种新型的反应型阻燃剂1-（2-羟基-3-磷杂菲）丙氧基-4-环氧丙氧基丁烷(1),其结构和性能经¹H NMR, ³¹P NMR, FT-IR和TG表征。以1为封端剂,聚氨酯（PU）为基材,制备了1/PU阻燃复合材料（2）,研究了1对2阻燃性能和力学性能的影响,初步探讨了1的阻燃机理。结果表明:1具有气相和凝聚相阻燃作用,2燃烧后可形成致密光滑炭层,使点燃时间延长,改善了燃烧熔滴现象。1含量为1%时,2¹的LOI为27%, UL-94燃烧等级为V-0级。     

2,3-二氯-5,6-二氰基-1,4-苯醌/NaNO2

设计了一种由 2,3-二氯-5,6-二氰基-1,4-苯醌(DDQ)和NaNO2组成的复合催化剂,该催化剂在9,10-二氢蒽氧化脱氢生成蒽的反应中表现出很高的催化活性和选择性. 在120 ℃和1.3 MPa O2下反应 8 h, 9,10-二氢蒽转化率达到99%以上,蒽的选择性为99%. 采用红外光谱和核磁共振方法对催化氧化脱氢的反应历程进行了研究. 结果表明, 9,10-二氢蒽氧气氧化脱氢生成蒽的反应是通过DDQ/DDQH2和NO2/NO两个氧化还原对的电子传递来推动的,以DDQ/NaNO2为催化剂可以有效催化9,10-二氢蒽氧化脱氢生成蒽.     

1,8-二羟基-9,10-二氢蒽的合成

以1,8-二羟基蒽醌为原料,经甲醚化,锌粉和金属钠还原,去甲基等4步反应合成1,8-二羟基-9,10-二氢蒽,总产率为37.1,8-二甲氧基蒽醌用NaBH₄/CF₃COOH还原生成二聚产物,并测定了其单晶结构.     

10,10-二吡啶甲基-9,10-二氢蒽的合成研究

蒽酮1和氯甲基吡啶盐酸盐2在甲苯中回流反应生成10,10-二吡啶甲基-9(10H)蒽酮(3),收率63％～68％;3用硼氢化钠还原生成10,10-二吡啶甲基-9,l0-二氢蒽-9-醇(4),收率87％～90％;蒽醇4在酸催化下发生歧化反应,得到还原产物10,10-二吡啶甲基-9,10-二氢蒽(5)和氧化产物蒽酮3.该歧化反应受催化剂、溶剂和反应温度等影响.当蒽醇4用三氟化硼为催化剂、甲苯为溶剂、回流反应,5的收率达到74％.所合成的新化合物都经1H NMR,13C NMR,MS和元素分析表征确认.     

Synthesis of poly(10-undecene-1-ol) by metallocene-catalyzed polymerization

Poly(10-undecene-1-ol)s as precursors for potential polar macromonomers were synthesized by metallocene-catalyzed polymerization. For the use as macromonomers, polymerizable terminal double bonds are an important requirement and thus, the investigation of the end groups in the polymers was the main focus of this study. The influence of the catalyst and polymerization conditions on the chain length of the polymer backbone, the monomer conversion as well as the end group characteristics were analyzed. It was possible to find conditions for preparing poly(10-undecene-1-ol)s with terminal double bonds using the catalyst system Cp₂ZrCl₂/MAO. Two other chosen catalysts produced mainly internal double bonds. The poly(10-undecene-1-ol)s could be prepared as atactic or isotactic-rich materials depending on the catalyst used.     

DFT Comparison the Performance of Pd10Sn5 and Pd10Ag5 Electrocatalyst for Reduction of CO2

CO₂ electrocatalysis as a hydrocarbon is a promising means of achieving economical CO₂-mediated hydrogen energy cycling. Hydrocarbons are renewable hydrogen storage materials. The development of reliable metal alloy electrocatalysts is an urgent but challenging task associated with such systems, although there is still a lack of precise reaction mechanism design. In this study, the performance of Pd₁₀Ag₅ alloy nanoparticles (NPs) and Pd₁₀Sn₅ alloy nanoparticles (NPs) on the electrocatalytic reaction of CO₂ was compare. The kinetic and density functional theory (DFT) calculations show that the selectivity of the Pd-based bimetallic catalyst to the C2 product is greater than that of C1, and the stability of Pd₁₀Ag₅ is better and less affected by the reaction environment. However, the catalytic performance of the Pd₁₀Sn₅ electrocatalyst in the liquid phase is the best. The insight obtained from the calculations is used to develop criteria for identifying new and improved catalysts for electrochemical CO₂ reduction.     

Montmorillonite K-10-catalyzed intramolecular rearrangement of vinylidenecyclopropanes

A series of naphthalene, indene, and 6aH-benzo[c]fluorene derivatives are synthesized by intramolecular rearrangement of vinylidenecyclopropanes using a heterogeneous solid acid catalyst, montmorillonite K-10, under mild reaction conditions in good to excellent yields. The solid acidic catalyst, montmorillonite K-10, can be recovered and reused.     

Dechlorination of Aromatic Chlorides in Aqueous System Catalyzed by Functionalized MontK10 Supported Palladium—tin

A novel bisupporter binetal catalyst PVP-PdCl2-SnCl4/MonK10-PEG400,using for dehalogenation of insoluable aromatic halides in aqueous system,has shown high dechlorination activity and selectivity,without any organic solvent or phase transfer catalyst.The conversion of aromatic chlorides can reach 100%.The catalyst is easy to prepare and has good reusability.     

XiDehalogenation of Aryl Halides Catalyzed by MontK10 Immobilized PVP-Pd-Sn Catalyst in Aqueous System

Catalytic dehalogenation of organic halides is of great value to the organic synthesis and for the preventing of environmental pollution. Although, in recent years, there are many reports describing dehalogenation of organic halides in the literature1,2,3, most of them were carried out in the organic system,only few examples4,5 of dehalogenation were carried out in aqueous system. The toxic aryl halides may contaminate and harm human being seriously through food chain. Therefore, it is of utmo…     

Acylation of aromatic alcohols and phenols over InCl3/montmorillonite K-10 catalysts

Montmorillonite K-10 clay supported InCl₃ is a highly active catalyst for the acylation of aromatic alcohols and phenols with different acyl chlorides. This catalyst can be reused in reactions a number of times without very significant loss of catalytic activity     

Montmorillonite K-10 as a Reusable Catalyst for Fischer Type of Glycosylation under Microwave Irradiation

Montmorillonite K10 catalyzed Fischer type glycosylation was studied for various monosacharides with different alcohols under microwave irradiation. The method was found to be efficient, economic, simple and time saving and the catalyst montmorillonite K-10 was reused three times without loss of catalytic activity and anomeric selectivity. With glycerol, the method gave products glycosylated at primary alcohols only.     

Effects of pretreatment and reduction on the Co/Al2O3 catalyst for CO hydrogenation

The purpose of this study was to investigate the effect of preadsorbed CO at different temperatures, calcination temperatures, the combined influence of reduction temperature and time, and pretreatment using hydrogen or syngas as reduction agents on the F-T synthesis （FTS） activity and selectivity of Co/Al2O3 catalyst. The reactivity of the carbon species at higher preadsorption temperature with H2 in TPSR decreased, whereas the carbon-containing species showed higher reactivity over Co/Al2O3 catalyst with low calcination temperature. This agreed well with the order of catalytic activity for F-T synthesis on this catalyst. The catalytic activity of the catalyst varied with reduction temperature and time remarkably. CODEX optimization gave an optimum reduction temperature of 756 K and reduction time of 6.2 h and estimated C5＋ yield perfectly. The pretreatment of Co/Al2O3 catalyst with different reduction agents （hydrogen or syngas） showed important influences on the catalytic performance. A high CO conversion and C5＋ yield were obtained on the catalyst reduced by hydrogen, whereas methane selectivity on the catalyst reduced by syngas was much higher than that on the catalyst reduced by hydrogen.     

Synthesis of ethyl acetate by esterification of acetic acid with ethanol over a heteropolyacid on montmorillonite K10

In present work, liquid phase esterification of acetic acid with ethanol over dodecatungestophosphoric acid (DTPA) supported on K10 montmorillonite was systematically studied and optimization of process parameters was carried out. The 20% m/m DTPA/K10 was found to be the optimum catalyst with 90% acetic acid conversion and 100% ethyl acetate selectivity. The study was also explored to see the feasibility of 20% m/m DTPA/K10 as a catalyst for the alkylation of acetic acid with other alcohols like methanol, iso-propanol and n-butanol. The 20% m/m DTPA/K10 has shown increased activity with the increase in carbon number, at the same alcohol reflux. The results are novel.