酸催化甘油与苯甲醛缩合制备六元环缩醛

比较了对甲苯磺酸(PTSA)、磷钨酸(PWA)、KHSO4和FeCl3催化对甘油与苯甲醛的缩合反应收率,及对产物中六元环缩醛5-羟基-2-苯基-1,3-二氧六环(1)与五元环缩醛4-羟甲基-2-苯基-1,3-二氧五环(2)比例的影响。当以环己烷为带水剂及苯甲醛与甘油的摩尔比为2∶3的情况下,KHSO4为催化剂的缩合产物(1+2)收率较高,为96.8%;PTSA催化的缩合产物中,化合物1的比例最高(m(1)∶m(2)=48.6∶51.4)。室温下PTSA、PWA、KHSO4和FeCl3均可催化化合物2向化合物1的转化。在-20℃下,只有PTSA能催化化合物2向化合物1的转化。在-20℃,PTSA催化化合物2转化成化合物1a,并以晶体形式从苯(40%)-石油醚(60%)中析出。母液循环转化3次后,化合物1a的累计收率可达91.1%。     

新型苯并咪唑衍生物的合成

以苯甲醛甘油缩醛和对甲基苯甲醛甘油缩醛为原料,采用次氯酸钠催化氧化法,制得2-芳基-4-羧基-1,3-二氧戊环中间体;中间体分别与邻苯二胺或N-甲基邻苯二胺反应,合成了4种新型苯并咪唑衍生物(3a~3d),收率为78.0%~80.5%,其结构经UV, ¹H NMR, ¹³C NMR, IR和HR-MS(ESI)表征。      

金刚烷负载高价碘试剂的合成及氧化反应活性

以1,3,5,7-四氨基金刚烷与4-碘苯基酰氯为原料,经酰化、氧化反应,制备了新型金刚烷负载的高价碘试剂(1a-1c)。 酰化反应以CH₂Cl₂为溶剂,首先,0 ℃,反应4 h,然后室温反应2 h,投料比n(1,3,5,7-四氨基金刚烷)∶n(4-碘苯基酰氯)∶n(三乙胺)=1∶4.4∶5.2。 氧化反应以CH₂Cl₂/醋酸(体积比1∶1)为溶剂,间氯过氧苯甲酸(m-CPBA)为氧化剂,室温反应12 h,投料比n(2)∶n(m-CPBA)=1∶12。 化合物1a,1b和1c的总收率分别为86.4%、85.4%和85.3%。 以化合物1a-1c为氧化剂,在四甲基哌啶氮氧化物(TEMPO)催化下各类醇被氧化成相应的醛或酮,产物收率87%~100%。 负载碘苯2a-2c可以被方便地分离和回收,平均回收率98%,可再经氧化,高收率转化成化合物1a-1c,循环利用。     

FeCl3催化合成巴比妥酸的烷基化衍生物

以苯乙酮和苯甲醛为起始原料,经缩合、还原两步反应合成9个查尔醇（4a~4i）;以FeCl₃为催化剂,室温条件下,在二氯甲烷中实现了1,3-二甲基巴比妥酸与查尔醇4a~4i的烷基化反应,合成了9个巴比妥酸的烷基化衍生物（5a~5i）,其中5b~5i为新化合物,其结构经¹H NMR, ¹³C NMR和HR-MS(ESI)表征。     

FeCl3催化4-羟基香豆素烷基化衍生物的合成

以4-羟基香豆素、查尔醇（或苄醇）为原料,FeCl₃作催化剂,1,2-二氯乙烷作溶剂,在室温下实现了4-羟基香豆素的烷基化反应,高效合成了10个4-羟基香豆素的烷基化衍生物（3a~3e, 5a~5e）,收率70%~91%和67%~78%。在此基础上,利用FeCl₃/DDQ催化体系的一锅法串联环化反应合成了一系列2,4-二芳基-2H,5H-吡喃并[3,2-c]苯并吡喃-5-酮衍生物（6a~6d）,收率52%~85%。其中3b, 3d, 3e, 6b, 6c, 6d为新化合物,其结构经¹H NMR, ¹³C NMR和HR-MS（ESI）表征。     

Zn/Ni双金属接力催化:一锅法分子内环异构化/分子间酰胺化反应构建噁唑衍生物

报道了一种新型的Zn/Ni双金属接力协同催化的串联反应,该方法通过Zn（OTf）₂和Ni（ClO₄）₂·6H₂O协同接力催化,一锅法进行分子内环异构化/分子间酰胺化反应构建噁唑衍生物.产物的形成主要是由Zn（OTf）₂活化炔丙基酰胺的三键,发生分子内的环化反应构建噁唑啉中间体,由Ni（ClO₄）₂·6H₂O催化3-羟基-2-苯甲基-异吲哚啉-1-酮类化合物形成酰亚胺离子,继而由噁唑啉中间体与酰亚胺离子发生分子间酰胺化反应实现了噁唑分子的合成.优化部分的对比实验证实Zn（OTf）₂和Ni（ClO₄）₂·6H₂O的存在对于该串联反应都是必须条件.大体而言,所有反应都是将各反应物和试剂一次性加入,在空气氛围下100℃加热进行反应.含有不同类型给电子取代基、含有不同富电子的芳环、含有不同吸电子取代基的炔丙基酰胺都可以顺利地和3-羟基-2-苯甲基-异吲哚啉-1-酮反应得到相应的噁唑衍生物,相比而言,含有吸电子基团的炔丙基酰胺比含有给电子基团或富电子的炔丙基酰胺所得到的产物的收率要低一些,这可能是因为含有吸电子基团的炔丙基酰胺所得到的噁唑啉中间体活性较低.3-羟基-2-苯基异吲哚啉-1-酮类化合物、3-羟基-2-苯甲基异吲哚啉-1-酮类化合物和3-羟基-2-苯乙基异吲哚啉-1-酮类化合物对反应同样表现出了良好的兼容性.该方法反应条件简单、原子经济性高、官能团兼容性好,对噁唑衍生物合成和酰亚胺离子形成具有重要的意义.     

新型咔唑类卟啉的合成与性能

以咔唑、对氟苯甲醛和吡咯为原料制得meso-四（4-咔唑）苯基卟啉（TCPP）。以对硝基苯甲醛与吡咯为原料制得meso-四(4-硝基)苯基卟啉（TNPP）； TNPP经还原反应制得meso-四（4-氨基苯基）卟啉（TAPP）; TAPP与咔唑苯甲醛经缩合反应制得新型meso-四[对-（P-N-咔唑基亚苄基亚氨基）]苯基卟啉(TCIPP)，其结构和性能经UV-Vis, ¹H NMR, ¹³C NMR, IR,元素分析和循环伏安法（CV）表征。结果表明：TCPP在270~300 nm处有新吸收峰；TCIPP的Q带和B带相比于TCPP有明显红移。TCPP和TCIPP的E_LUMO和E_HOMO分别为-3.18 eV, -5.17 eV和-3.49 eV, -5.08 eV，两者的能级结构与纳米TiO₂的导带能级相匹配。     

meso-5，10，15，20-四[3，5-二（辛酰氧基）苯基]卟啉锌（铜）配合物的合成与性能

以3,5-二甲氧基苯甲醛和吡咯为原料,经缩合反应制得meso-5,10,15,20-四（3,5-二甲氧基苯基）卟啉（1）; 1与BBr-3-反应制得meso-5,10,15,20-四（3,5-二羟基苯基）卟啉（2）; 2与辛酰氯反应制得meso-5,10,15,20-四[3,5-二（辛酰氧基）苯基]卟啉（3）; 3分别与ZnCl₂和CuCl₂经配位反应合成了meso-5,10,15,20-四[3,5-二（辛酰氧基）苯基]卟啉锌配合物（4）和meso-5,10,15,20-四[3,5-二（辛酰氧基）苯基]卟啉铜配合物（5）,其结构经FL, UV-Vis, ¹H NMR, IR和元素分析确证。采用差示扫描量热法（DSC）和偏光显微镜研究了4和5的性能。结果表明：4和5为双变液晶,初始转变温度分别为31 ℃和28 ℃。     

新型卤代3-芳基香豆素的合成及其抗癌活性

以卤代芳基乙酸和2,3,4-三羟基苯甲醛为主要原料,经Perkin缩合和关环反应制得12个含卤素的7,8-二乙酰氧基-3-芳基香豆素化合物（D₁~D₁₂）; D₁~D₁₂经水解反应合成了12个含卤素的7,8-二羟基-3-芳基香豆素化合物（E₁~E₁₂）,除D₂, D₄~D6, E₂, E₄~E₆外均为新化合物,其结构经¹H NMR和MS（EI）表征。采用MTT法研究了D₁~E₁₂对人肺癌细胞株(A549)的体外细胞毒性。结果表明：D₁~E₁₂均表现出不同程度的肿瘤细胞增殖抑制活性（IC₅₀≥192.74 μmol·L^-1）。     

亚乙基桥联多取代茚-芴锆、铪配合物的合成、结构及催化丙烯选择性齐聚研究

合成并表征了一系列新型亚乙基桥联多取代茚-芴锆、铪配合物ansa-C₂H₄-{2-Me-3-Bn-5,6-[1,3-（CH₂）₃]Ind}-（Flu） ZrCl₂（C1）,ansa-C₂H₄-{2-Me-3-Bn-5,6-[1,3-（CH₂）₃]Ind}（2,7-^tBu₂-Flu） ZrCl₂（C2）,ansa-C₂H₄-{2-Me-3-Bn-5,6-[1,3-（CH₂）₃]Ind}（3,6-^tBu₂-Flu） ZrCl₂（C3）,ansa-C₂H₄-{2-Me-3-Bn-5,6-[1,3-（CH₂）₃]Ind}（Flu） HfCl₂（C4）,并对典型配合物进行了X射线单晶衍射分析,确定了其空间结构.研究了该系列配合物在助催化剂作用下催化丙烯齐聚的行为,考察了催化剂结构及反应条件对齐聚反应的影响.配合物C1～C4与改性甲基铝氧烷（MMAO）或三异丁基铝/三苯甲基四（五氟苯基）硼酸盐（TIBA/TrB）组成的催化体系对丙烯齐聚表现出中等到高的催化活性.锆配合物C2和C3在40～100℃条件下普遍具有较高的β-甲基消除（β-Me消除）选择性（最高可达86%）,实现了分子量M_n在400到4500 g·mol^－1范围内的烯丙基封端丙烯齐聚物的高效合成.铪催化剂体系C4/TIBA/TrB的β-Me消除选择性明显高于相应的锆催化剂体系,同时所得齐聚物的分子量更低.     

Oxidation of 1,3-Dioxacycloalkanes with Complexes of Potassium Chlorochromate and Chlorodiperoxochromate with 15-Crown-5, Catalyzed with 2,2,5,5-Tetramethyl- 4-phenyl-3-oxo-3λ5-imidazolin-1-yloxyl

2,2,5,5-Tetramethyl-4-phenyl-3-oxo-3⁵-imidazolin-1-yloxyl catalyzes oxidation of 2-isopropyl-1,3-dioxolane, 2-phenyl-1,3-dioxolane, 2-phenyl-4-chloromethyl-1,3-dioxolane, and 2-phenyl-1,3-dioxane with 15-crown-5 complexes of potassium chlorodiperoxochromate (KCrO₅Cl·2C₁₀H₂₀O₅) and potassium chlorochromate (KCrO₃Cl·2C₁₀H₂₀O₅). 2-Isopropyl-1,3-dioxolane is oxidized to the corresponding monoester in quantitative yield, and the 2-phenyl derivatives yield benzaldehyde. The spiro ketal, 2,2-pentamethylene-4-methyl-1,3-dioxane, is decomposed to cyclohexanone.     

Oxidation of 1,3-Dioxacyclanes with Oxone and Potassium Persulfate Catalyzed by 2,2,5,5-Tetramethyl-4-Phenyl-3-Imidazoline-3-Oxide-1-Oxyl

The catalytic effect of 2,2,5,5-tetramethyl-4-phenyl-3-imidazoline-3-oxide-1-oxyl on the oxidation of 2-isopropyl-1,3-dioxolane, 2-phenyl-1,3-dioxolane, 2-phenyl-4-chlormethyl-1,3-dioxolane, 2-isopropyl-1,3-dioxane, 2-isopropyl-4-methyl-1,3-dioxane, 2-phenyl-1,3-dioxane, 2-phenyl-4-methyl-1,3-dioxane with oxone and potassium persulfate is reported. The corresponding glycol monoesters were obtained with yields of 90-100%.     

Polymerization and reaction of tetraoxane with various olefins catalyzed by BF3O·(C2H5)2

The copolymerization of tetraoxane with various olefins by BF₃·O(C₂H₅)₂ in ethylene dichloride at 30°C has been studied. The gas chromatographic technique was employed for the determination of concentration of each compound. The rate of tetraoxane consumption was decreased by the addition of olefins in the order of; no addition > trans-stilbene > styrene > 1,1-diphenylethylene > 2-chloroethyl vinyl ether > cyclohexene ≥ indene ≥ α-methylstyrene. The formation of the methanol-insoluble copolymer of tetraoxane and olefin was not confirmed. However, 4-methyl-4-phenyl-1,3-dioxane and 4,4-diphenyl-1,3-dioxane were formed in the reaction of tetraoxane with α-methylstyrene and 1,1-diphenylethylene, respectively. 4,4-Diphenyl-1,3-dioxane was identified on the basis of the molecular weight measurement, elemental analysis and NMR and infrared spectroscopy. On the other hand, 1,3-dioxane derivatives were not formed in the reaction of tetraoxane with α,β-disubstituted olefins. Monomer composition dependence of the copolymerization of tetraoxane with 1,1-diphenylethylene or α-methylstyrene has been studied. The amount of 4,4-diphenyl-1,3-dioxane formed reached a maximum at a monomer composition of 1:1 in the reaction of tetraoxane with 1,1-diphenylethylene. The formation of cyclic dimer of α-methylstyrene was suppressed by tetraoxane.     

Metal-free,PTSA catalyzed facile synthesis of β-ketoacetal from β-chlorocinnamaldehyde

A toluene solution of β-chlorocinnamaldehyde and dihydroxy alcohols in the catalytic presence of para-toluenesulphonic acid (PTSA) yield the β-ketoacetal in good to outstanding amount. The catalyst (PTSA), first selectively protect the aldehydic group to form the β-chloroacetal and the subsequent dechlorination by H₂O result the β-ketoacetal. Significant transformation was achieved with electron donating substituent attached at the para-position of cinnamaldehyde. The selective formation of β-keto-1,3-acetal was also obtained with a mixture of 1, 2- and 1, 3- diol. The present reaction consists of a metal-free, economical, robustly feasible, sizeable functional group tolerance and high yield properties. Moreover, the use of different dihydroxy alcohols made this process more benign and valuable towards the metal-free development of ketones. First, of its kind, a rare and unusual multitasking nature of PTSA is observed.     

Fluorocontaining 1,3-Dicarbonyl Compounds in the Synthesis of Pyrimidine Derivatives

Hexafluoroacetylacetone reacts with urea (thiourea) to yield respectively 4,6-bis(hydroxy)-4,6-bis(trifluoromethyl)hexahydropyrimidin-2-one(thione). The dehydration of the products and also reaction of nonsymmetrical fluoroalkyl-containing 1,3-diketones with urea (thiourea) afford substituted pyrimidines. The condensation of fluorinated 3-oxoesters and 1,3-diketones with benzaldehyde and urea (thiourea) results in 5-alkoxycarbonyl(acyl)-4-hydroxy-2-oxo(thioxo)-6-phenyl-4-fluoroalkylhexahydropyrimidines that on dehydration furnish 5-alkoxycarbonyl(acyl)-2-oxo(thioxo)-4-phenyl-6-fluoroalkyltetrahydropyrimidines. Ethyl 7-nonafluorobutyl-5-phenyl-2,3-dihydrothiazolo[3,2-a]pyrimidine-6-carboxylate hydrobromide forms in reaction of dibromoethane with ethyl ether of 2-thioxo-4-phenyl-6-nonafluorobutyltetrahydropyrimidine.     

Copolymerization of tetraoxane with styrene catalyzed by BF3·O(C2H5)2

The copolymerization of tetraoxane with styrene catalyzed by BF₃·O(C₂H₅)₂ was studied at 30°C. to determine whether a cyclic monomer can copolymerize with a vinyl monomer. The formation of the copolymer was confirmed by elementary analysis of both benzene-soluble and benzene-insoluble fractions of the polymer obtained. It was found by gas chromatography that a fairly large amount of 4-phenyl-1,3-dioxane and a small amount of trioxane were formed in the present system, in addition to polymers. Roughly a third of the total amount of the monomers reacted was consumed in the formation of methanol-insoluble polymer, a third for 4-phenyl-1,3-dioxane, and another third for trioxane and unknown products which could not be indentified. The formation of these cyclic compounds during the copolymerization may be explained in terms of a back-biting (or intramolecular transacetalization) reaction. The cationic reactivity of tetraoxane was found to be similar to that of styrene on the basis of both the consumption rate of each monomer in the copolymerizing system and the composition of the methanol-insoluble polymer obtained.     

Regiospecific cleavage of 1,3-dioxanes by organoaluminum compounds

Organoaluminum compounds react with 4-methyl-2-phenyl-1,3-dioxane with cleavage of the O₁-C₂ bond to give monoethers with a primary alcohol group.Translated from Khimiya Geterotsiklicheskikh Soedinenii, No. 8, pp. 1036–1037, August, 1985.     

Acidolysis of poly(4-methyl-1,3-dioxolane)

The onset of decomposition of poly(4-methyl-1,3-dioxolane) was lowered to 70°C by 0.1 wt% p -toluene sulfonic acid from 170°C in the absence of acid to produce more than 81% yield of monomer. Protonation forms cyclic oxonium ion followed by depolymerization. Minor products are isomers of hydroxymethyl-2-hydroxyl-2-methyl ethyl ether and bis(2-hydroxyl-2-methyl ethoxyl)methane from rearrangements of the oxonium ions. The first order rate constant of acidolysis of poly(4-methyl-1-1,3-dioxolane) is about 8.5 kcal mol^?1, which is much smaller than about 17 kcal mol^?1 for the acidolysis of poly(1,3-dioxolane).     

A novel and facile synthesis of 2-(cyclohexylamino)-6,7-dihydro-3-aryl-1H-indole-4(5H)-ones via a one-pot multi-component reaction

A simple and efficient synthesis of 2-(cyclohexylamino)-6,7-dihydro-3-aryl-1H-indole-4(5H)-ones was achieved via a one-pot multi-component reaction of cyclohexyl isocyanide, an aldehyde, a 1,3-dicarbonyl compound, and ammonium acetate in the presence of a catalytic amount of KHSO₄ in acetonitrile.     

4,7-二苯基-1,10-菲啰啉的合成研究

以4-苯基-8-硝基喹啉为起始原料,经还原得到4-苯基-8-氨基喹啉,再以I2/KI为氧化剂,在乙酸和盐酸的存在下,用Skraup法合成了4,7-二苯基-1,10-菲啰啉.化合物结构经IR和1H NMR得到了证实.实验研究得到了最佳的合成条件为:n(3-氯苯丙酮)∶n(4-苯基-8-氨基喹啉)=1.5∶1,I2/KI用量为8%,反应温度120℃,反应时间2.5 h.产品收率可达82%.