1,3-丙二硫醇替代试剂1-（1,3-二噻-2-亚基）丙酮的缩硫醛/酮化反应

通过易制备的3-(1,3-二噻-2-亚基)-2,4-戊二酮(1b)在酸性条件下的脱乙酰化反应制得1-(1,3-二噻-2-亚基)丙酮(1f),产率为86%. 在MeCOCl/MeOH体系中,常温或回流条件下,化合物1f能作为有效的1,3-丙二硫醇替代试剂与醛和酮进行缩硫醛/酮化反应,高产率(86%～99%)合成1,3-二噻烷衍生物. 与已报道的替代试剂2-(2,4-二氯-1,4-戊二烯-3-亚基)-1,3-二噻烷(1a)、3-(1,3-二噻-2-亚基)-2,4-戊二酮(1b)、2-(1,3-二噻-2-亚基)-3-羰基丁酸甲酯(1c)、2-(1,3-二噻-2-亚基)-3-羰基丁酰胺(1d)和2-(1,3-二噻-2-亚基)-3-羰基丁酸(1e)相比,化合物1f是活性最好的1,3-丙二硫醇替代试剂.     

无气味的二硫缩烯酮作为1,3-丙二硫醇替代试剂的缩硫醛/酮化反应

探讨了将3-[1,3]二噻-2-亚基-2,4-戊二酮及其衍生物作为一种无气味、易于制备、便于贮存、使用方便的1,3-丙二硫醇替代试剂在缩硫醛/酮化反应中的应用.     

2-(1,3-亚丙二硫)亚甲基-3-羰基丁酸作为硫醇替代试剂在缩硫醛/酮化反应中的应用

探讨了以2-(1,3-亚丙二硫)亚甲基-3-羰基丁酸作为硫醇替代试剂,乙醇作溶剂的缩硫醛/酮化反应.实验结果表明,该硫醇替代试剂能与各类醛、酮化合物快速、顺利地进行缩硫醛/酮化反应,以较高的产率生成相应的1,3-二噻烷类化合物.同时,该缩硫醛/酮化反应对不同的醛、酮化合物具有较高的化学选择性.     

4,4-二乙硫／苄硫基-3-烯-2-丁酮的合成及其作为无气味硫醇替代试剂的缩硫醛/酮化反应

经由3-(二乙硫／苄硫基)亚甲基-2,4-戊二酮(1)的酸催化脱乙酰基反应高产率地合成了4,4-二乙硫／苄硫基-3-烯-2-丁酮(2). 化合物2作为无气味的乙硫醇及苄硫醇替代试剂能与各种醛／酮在温和的反应条件下生成相应的缩硫醛／酮.     

肟的无气味硫缩醛/酮化反应

探讨了以无气味且稳定的α-羰基二硫缩烯酮(1)作为代硫醇试剂的肟(2)的硫缩醛/酮化反应. 在乙酰氯-乙醇(体积分数95%)或4-十二烷基苯磺酸(DBSA)-水体系中及回流条件下, 化合物1与肟2能有效地进行硫缩醛/酮化反应. 反应过程中未闻到硫醇的恶臭气味.     

噻烯衍生物的水相合成

探讨了无气味和稳定的1-[1,2-亚乙基(或1,3-亚丙基)二硫]亚甲基丙酮(1c)作为代硫醇试剂的水相噻烯合成反应。在4-十二烷基苯磺酸(DBSA)-水体系和回流条件下,1c与α-溴代酮/安息香(2)能有效地进行缩合反应,合成噻烯衍生物(3)。反应过程中没有闻到硫醇的恶臭气味。     

官能化二硫缩烯酮的选择性α-溴代反应

发展了一种适用范围广、高效且高选择性的官能化二硫缩烯酮的α-溴代反应.在少量水存在下,在四氢呋喃溶液中,以溴化铜为溴代试剂,经由官能化二硫缩烯酮(1)的α-溴代反应制备了结构多样的α-溴代二硫缩烯酮(2).     

α,α-二乙酰基二硫缩烯酮和芳醛的缩合反应研究

在碱性条件下,α,α-二乙酰基二硫缩烯酮和芳醛的缩合反应受烷硫基的影响.α,α-二乙酰基二苄硫缩烯酮1和芳醛3缩合生成单面缩合脱乙酰基产物α-肉桂酰基二苄硫缩烯酮4;α,α-二乙酰基环二硫缩烯酮2和芳醛3缩合生成双面缩合产物α,α-二肉桂酰基环二硫缩烯酮5.     

3-苯基-4-氯-1,3,4-二氮磷杂环戊-2-硫酮的合成及其除草活性研究

报道了苯基硫脲与脂肪醛(酮)及三氯化磷进行的类Mannich反应,除生成预期产物3-苯基-4-氯-4-氧代-1,3,4-二氮磷杂环戊-2-硫酮(Ⅰ)外,还生成了少量3-苯基-4-氯-4-硫代-1,3,4-二氮磷杂环戊-2-硫酮(Ⅱ).当Ⅰ与Lawesson试剂在甲苯中反应时,可顺利地转化为Ⅱ.生物测定结果表明,Ⅱ具有较好的选择性除草活性.晶体结构测定表明,Ⅱ的五元磷杂环为平面结构.     

对苯二甲醛或间苯二甲醛与5，5-二甲基-1，3-环己二酮的反应：含有双4（日）-吡喃、1，4-二氢吡啶结构单元的杂环化合物的合成

用对苯二甲醛或间苯二甲醛与5，5-二甲基-1，3-环己二酮反应，在不同条件下得到了含有双4(H）-吡喃、1，4_二氢吡啶结构单元的双一氧杂蒽衍生物、双-吖啶衍生物、以及双-AL羟基吖啶衍生物．     

Chemoselective thioacetalization in water: 3-(1,3-dithian-2-ylidene)pentane- 2,4-dione as an odorless, efficient, and practical thioacetalization reagent

A chemoselective thioacetalization utilizing 3-(1,3-dithian-2-ylidene)pentane-2,4-dione as a novel nonthiolic, odorless 1,3-propanedithiol equivalent catalyzed by p-dodecylbenzenesulfonic acid in water has been developed.     

Preparation, reactivity and tautomeric preferences of novel (1H-quinolin-2-ylidene)propan-2-ones

1,1-Difluoro-3-(1H-quinolin-2-ylidene)propan-2-one 1a, 1,1,1-trifluoro-3-(1H-quinolin-2-ylidene)propan-2-one 1b, 1,1,1-trifluoro-3-(4-chloro-1H-quinolin-2-ylidene)propan-2-one 1c and 1,3-dibromo-1,1-difluoro-3-(2-quinolyl)propan-2-one 2 are prepared and characterized by various spectroscopic techniques. The crystal structure of 1a is determined by X-ray diffraction. Furthermore, a series of previously known non-halogenated (1H-quinolin-2-ylidene)propan-2-ones 1d-1h are oxidized with AgBrO₃ in the presence of AlCl₃. In all cases, 2-(1-bromo-1-chloromethyl)quinoline 3 is obtained in high yield. The bromination order and sites of 1a are analyzed based on ab initio MP2 and DFT calculations for the molecule and its anions.     

Tautomerism in quinaldyl ketones

The quinaldyl ketone, 4-phenyl-3-(quinolin-2-yl)-butan-2-one was prepared by two methods: (a) benzylation of 1-(1H-quinolin-2-ylidene)propan-2-one in the presence of sodium hydride in dimethylformamide and (b) by the benzylative demethoxycarbonylation of methyl 2-(1H-quinolin-2-ylidene)-3-oxobutanoate in the presence of lithium bromide in hexamethylphosphoramide at 135°. In the absence of acid, the compound exists exclusively in the tautomeric form, 4-phenyl-3-(1H-quinolin-2-ylidene)butan-2-one.     

Hartree-Fock, Møller-Plesset calculations and dynamic NMR study of 3,3-dimethoxy-1-(imidazolidin-2-ylidene)propan-2-one

The experimental (1)H, (13)C NMR spectra of 3,3-dimethoxy-1-(imidazolidin-2-ylidene)propan-2-one were recorded in CDCl(3) at temperature range 213-323 K. The variable temperature spectra revealed a dynamic NMR effect which is attributed to restricted rotation around the C=C double bond. Fast exchange processes of deuterium atoms between CDCl(3) and 3,3-dimethoxy-1-(imidazolidin-2-ylidene)propan-2-one or fast exchange of proton between nitrogen and oxygen atoms of carbonyl group is also revealed by broadening of N-H (singlet) proton NMR signals. Proton and carbon theoretical chemical shifts of the title molecule were calculated by using RHF and MP2-GIAO levels and different basis sets in gas phase at 298 K. The calculated proton chemical shifts show that the experimental values have no agreement with theoretical values, but for carbon chemical shifts a good agreement achieved by using RHF with 6-31G basis set and MP2/3-21G, 6-31G basis sets. Discrepancies are attributed to either the limitations of calculating program, because the change of the structure while rotation are not considered. The results showed that to select of basis set has more important rule, because RHF-GIAO level calculation with 6-31G basis set in gas phase can excellently reproduce the (13)C NMR spectrum. Moreover, MP2/3-21G, 6-31G calculation has not significant influence on (13)C NMR chemical shifts with respect to RHF-6-31G.     

常山酮中间体的合成工艺改进

以2-乙酰呋喃为起始原料,经扩环、甲基化、去质子化、亲核加成、缩酮化、Rh/C催化氢化及水解等反应合成了常山酮中间体--1-(3-甲氧基哌啶-2-基)丙酮,总收率40.2%,其结构经¹H NMR和ESI-MS确证。     

Simple and regioselective bromination of 5,6-disubstituted-indan-1-ones with Br2 under acidic and basic conditions

Bromination of 5,6-dimethoxyindan-1-one with Br(2) in acetic acid at room temperature produced exclusively the corresponding 2,4-dibromo compound in 95% yield. Reaction of 5,6-dimethoxyindan-1-one with Br(2) in the presence of KOH, K(2)CO(3) or Cs(2)CO(3 )at ~0 degrees C( )gave the monobrominated product 4-bromo-5,6-dimethoxyindan-3-one in 79%, 81% and 67% yield, respectively. 5,6-Dihydroxyindan-1-one was dibrominated on the aromatic ring affording 4,7-dibromo-5,6-dihydroxyindan-1-one both in acetic acid at room temperature and in the presence of KOH at ~0 degrees C. 5,6-Difluoroindan-1-one and 1-indanone were alpha-monobrominated in acetic acid and alpha,alpha-dibrominated under KOH conditions at room temperature.     

Synthesis of 1,3-dithianes and 1,3-dithiolanes. Baker's yeast reduction and lipase-catalyzed resolution for synthesis of enantiopure derivatives.

Three 1,3-dithiolanes and four 1,3-dithianes have been synthesised from 1-(1,3-dithiolan-2-yl)-2-propanone and 1-(1,3-dithian-2-yl)-2-propanone, respectively. Asymmetric reductions of these ketones using baker's yeast gave the corresponding enantiopure (S)-alcohols. Baker's yeast also reduced the double bond in 3-(1,3-dithian-2-yl)-3-buten-2-one enantioselectively to give (S)-3-(1,3-dithian-2-yl)-2-butanone. 3-(1,3-Dithian-2-yl)-3-buten-2-one was also reduced chemo-selectively and the resulting 3-(1,3-dithian-2-yl)-3-buten-2-ol was resolved by transesterification in organic solvent using lipase B from Candida antarctica to yield the (S)-alcohol and the (R)-acetate with very high enantiomeric ratio, E. Racemic 1-(1,3-dithiolan-2-yl)-2-propanol and 1-(1,3-dithian-2-yl)-2-propanol were also resolved under similar conditions to give the (S)-alcohols and the corresponding (R)-acetates.     

Dynamic Ring-chain Equilibrium of Nucleophilic Thiol-yne “Click” Polyaddition for Recyclable Poly(dithioacetal)s

We report a dynamic polymerization system based on the reversible nucleophilic Michael polyaddition of activated alkynes and dithiols. Four poly(dithioacetal)s(P1-P4) were prepared via the base-catalyzed thiol-yne "click" polyaddition of two dithiols(1,4-butanedithiol(4 S) and 1,5-pentanedithiol(5 S)) and two alkynones(3-butyn-2-one(Y1) and 1-phenyl-2-propyn-1-one(Y2)) at high concentrations. We systematically investigated the base-catalyzed polymerization of 4 S and Y1(for polymer P1) under dif...