丙二腈及氰乙酸酯参与的3-脱氢莽草酸甲酯缩合-芳构化-环合串联反应

3-脱氢莽草酸甲酯与丙二腈、氰乙酸乙酯及氰乙酸甲酯等活性亚甲基化合物在一定条件下发生缩合、芳构化及环合反应,可方便地构建C—C键并得到多取代的2-氨基苯并呋喃类化合物(3a~3e,4a和4b),其中化合物3a中的氰基和甲氧羰基可分别进行选择性水解.该方法具有原料易得、条件温和、操作简单及收率高等优点,为可再生生物质资源莽草酸的多样化转化和利用提供了新思路.     

3-脱氢莽草酸甲酯、乙酯的合成与表征

以莽草酸为起始原料,在酰化试剂二氯亚砜作用下,分别与甲醇和乙醇发生酯化反应得到莽草酸甲酯及乙酯,然后以四氢呋喃为溶剂,在氧化剂2-碘酰基苯甲酸(IBX)作用下,制备得到3-脱氢莽草酸甲酯和3-脱氢莽草酸乙酯.本方法采用可再生原料莽草酸为起始物,以性能温和、选择性好、绿色环保的IBX为氧化剂,具有操作简便、收率高等优点....     

一种Fe3+荧光探针的合成及其检测性能研究

金属离子的高效检测对于人类健康和环境保护极其重要。本文通过对甲基苯磺酸催化下3-脱氢莽草酸甲酯与若丹明6G乙二胺缩合的芳构化反应合成了一种检测Fe~(3+)的荧光探针分子Rh M606。该探针分子在乙醇溶液中特异性地与Fe~(3+)络合,导致若丹明内酰胺开环,在553nm处出现强的荧光发射峰。该荧光探针对Fe~(3+)具有良好的选择性,可定量检测水中的Fe~(3+),检测限为3. 93μmol/L。     

非贵金属Co-N-C/MgO高效催化糠醛氧化酯化制糠酸甲酯（英文）

设计开发绿色、可持续的生物质资源高效转化制化学品催化过程具有重要的科学与应用研究价值.生物质基平台分子糠醛在分子氧存在下与甲醇发生氧化酯化,提供了一条糠酸甲酯的"非石油基"合成新路线.该反应采用贵金属/非贵金属催化体系,目前通常需要引入K_2CO_3或CH_3ONa等碱性添加剂,以提高催化氧化酯化反应活性和选择性;但是存在活性组分流失、生成副产物及污染环境等问题,阻碍了其进一步应用.探索高性能非贵金属催化剂,实现无碱条件下糠醛高效氧化酯化,对于提高该生物质路线竞争力与推动工业化进程具有重要意义.本文利用浸渍法将1,10-邻菲罗啉合钴(Ⅱ)负载到碱性载体氧化镁上,在氮气气氛下800 ℃热解,制备了非贵金属Co-N-C/MgO催化剂.在糠醛氧化酯化制糠酸甲酯反应中,Co-N-C/MgO催化剂表现出优异的性能,在0.5 MPa O_2,100 ℃条件下反应12 h,糠醛转化率达到93.0%,糠酸甲酯选择性达到98.5%,远超过相同方法制备的其他载体(活性炭、NaX、NaY和CaO)负载的钴基催化剂,实现了无碱性添加剂条件下糠醛高效氧化酯化制糠酸甲酯.X射线光电子能谱、X射线衍射、透射电镜、元素分析以及对比实验结果表明,Co-N-C/MgO催化剂上可能存在含钴的氮掺杂碳物种;该催化剂在糠醛氧化酯化中的高性能与其脱氢能力密切相关.并且在0.3–1.0 MPa氧气压力范围内,Co-N-C/MgO催化糠醛氧化酯化过程基本不受压力变化影响.糠醛与甲醇的氧化酯化反应和缩合反应为两个竞争路径,反应路径决定了反应的主要产物.我们使用盐酸处理Co-N-C/MgO催化剂,脱除MgO载体,制备了Co-N-C(HCl)催化剂.当使用该催化剂时,糠醛与甲醇主要发生缩合反应,得到缩醛产物2-(二甲氧基甲基)呋喃.如果在Co-N-C(HCl)催化反应体系中引入MgO添加剂,则主要发生糠醛氧化酯化反应,主产物为糠酸甲酯.为了验证-Cl是否对反应产生影响,使用NaCl溶液对Co-N-C/MgO进行浸渍、清洗处理,或直接使用NaCl为添加剂-;在这两种情况下,糠醛转化率与糠酸甲酯选择性均下降,表明Cl对糠醛氧化酯化反应具有负面作用.根据实验结果,阴离子-(Cl)可能与℃(Ⅱ)中心发生配位,从而影响了金属活性中心的催化性能.Co-N-C(HCl)加入氧化镁,使得糠醛主要遵循氧化酯化路径进行转化,降低-Cl对Co-N-C(HCl)催化活性中心的影响.以上研究可为生物质基醛类化合物氧化酯化转化过程以及高性能非贵金属催化剂的设计开发提供有益参考.     

甲烷在Mo/HZRP-1催化剂上无氧脱氢芳构化反应 Ⅰ.Mo/HZRP-1催化剂的催化性能和积炭行为

用高硅含磷五员环沸石分子筛(商品代号HZRP-1)作为载体,制备了Mo/HZRP-1催化剂.与Mo/HZSM-5相比,Mo/HZRP-1对甲烷无氧脱氢芳构化反应也表现出较好的催化性能.实验过程中,在反应气中添加N2作为内标物,给出包括甲烷在Mo/HZRP-1上的结焦量、转化率及各产物选择性在内的总碳物料平衡计算结果.考察了不同Mo担载量对催化剂性能和积炭行为的影响;重点考察了不同温度焙烧后20%Mo/HZRP-1催化剂的性能和积炭行为.在反应的初始阶段,6%Mo/HZRP-1表现出很高的活性:反应进行30 min时,甲烷转化率为11%,芳烃选择性达81%,而催化剂的结焦选择性仅为12%.BET,NH3-TPD和催化反应等表征结果表明:Mo物种的数量和状态,分子筛的酸强度和酸量以及分子筛的孔道结构是决定甲烷无氧脱氢芳构化反应性能和积炭行为的关键因素.     

均相体系中铱催化2-取代-1,2-二氢喹啉类化合物的脱氢芳构化

 采用原位制备的铱双膦(或膦氮)配合物在碘存在下催化2-取代-1,2-二氢喹啉、2-甲基-2,3-二氢吲哚、1,4-二氢吡啶及3,4-二氢异喹啉等化合物的脱氢芳构化反应, 并考察了不同金属前体、配体、催化剂用量、溶剂和碘等因素对反应速率和选择性的影响. 结果表明,原位制备的［Ir(COD)Cl］2/(±)-MeO-Biphep在碘的存在下催化2-取代-1,2-二氢喹啉的脱氢芳构化反应速率快, 选择性好,催化剂的用量少; 对1,4-二氢吡啶和2,3-二氢吲哚的催化脱氢芳构化反应则须在高温下进行; 而对 3,4-二氢异喹啉, 即使在加热回流条件下也只有不到5%的转化率. 催化体系中碘的存在可以明显提高反应速率.     

HZSM-5/Hβ复合分子筛的正辛烷临氢异构化和芳构化性能

将不同孔尺寸、酸强度的HZSM 5和Hβ分子筛混合制得复合载体,担载金属组分Ni、Mg、Mo、Zn制得烷烃异构化和芳构化催化剂M/C。采用XRD、BET、程序升温氨脱附（NH3 TPD）及吡啶吸附 脱附红外光谱法对制备的载体及催化剂进行了理化性质表征。以正辛烷为正构烷烃模型化合物,在连续加氢微型反应装置上评价了催化剂对正构烷烃异构化和芳构化反应的催化性能。结果表明,与单一分子筛相比,复合后载体的表面酸中心分布得到了调节,中强酸中心的增加有利于烷烃异构化和芳构化反应。复合分子筛催化剂引入不同金属组分进行改性后体现出不同的催化性能,其中Ni的引入既提供了加脱氢活性中心,又获得了适宜的B、L酸中心分布,使反应转化率和选择性显著提高。反应条件对催化剂的异构化和芳构化性能也有不同程度的影响,在320℃、2.8MPa、2.0h－1下,正辛烷的临氢异构化和芳构化选择性较好。     

Pd/C促进的四氢异喹啉高选择性部分脱氢(英文)

采用K3PO4?3H2O修饰的Pd/C为催化剂实现了取代四氢异喹啉高选择性部分脱氢,并成功地避免了当量有害氧化剂的使用.多相催化剂Pd/C对四氢异喹啉化合物具有催化脱氢活性,但反应选择性较差,同时产生完全脱氢的芳构化产物异喹啉.而K3PO4?3H2O修饰的Pd/C催化剂能有效提高脱氢反应的化学选择性,在最优条件下可获得最高89%的分离收率.这为取代3,4-二氢异喹啉的合成提供了一种简便、高原子经济性和高化学选择性的反应途径.此外,该多相催化剂可回收循环使用多次,且活性和选择性基本保持不变.     

TS-1/H2O2碱溶液中低温氧化愈创木酚制备马来酸（英）

可再生生物质资源的开发与利用能够缓解化石燃料产生的温室气体对环境的负面影响.在生物质燃料制备过程中联产高附加值化学品能大幅提高生物质炼制的经济性.愈创木酚是常见的木质纤维素快速热解产物.本文研究了低温液相氧化愈创木酚制备马来酸,并重点考察了催化剂添加量、pH值、反应时间和反应温度等反应条件的影响.研究发现,在钛硅沸石-过氧化氢碱溶液氧化反应体系中（80℃,pH=13.3）,20₃0mol%的愈创木酚可以选择性转化为马来酸.同时初步探讨了愈创木酚氧化开环转化为马来酸的反应机理.     

非贵金属Co-N-C/MgO高效催化糠醛氧化酯化制糠酸甲酯

设计开发绿色、可持续的生物质资源高效转化制化学品催化过程具有重要的科学与应用研究价值.生物质基平台分子糠醛在分子氧存在下与甲醇发生氧化酯化,提供了一条糠酸甲酯的"非石油基"合成新路线.该反应采用贵金属/非贵金属催化体系,目前通常需要引入K2CO3或CH3ONa等碱性添加剂,以提高催化氧化酯化反应活性和选择性;但是存在活性组分流失、生成副产物及污染环境等问题,阻碍了其进一步应用.探索高性能非贵金属催化剂,实现无碱条件下糠醛高效氧化酯化,对于提高该生物质路线竞争力与推动工业化进程具有重要意义.     

Features of photolytic transformation of [4-(2-methyl-5-t-butyl-cyclohexadiene-1,5-dion-3,4-yl)-3-methyl-6-<Emphasis Type="Italic">tert</Emphasis>-butyl-catecholato]triphenylantimony(V)

Photolysis of [4-(2-methyl-5-tert-butyl-cyclohexadiene-1,5-dion-3,4-yl)-3-methyl-6-t-butyl-catecholato] triphenylantimony(V) in toluene by irradiation with the light of wavelength 546 nm leads to excitation of the molecule of parent compound which reacts with a molecule of Ph3SbCatQ affording 4,4′-di-(3-methyl-6-tert-butyl-o-benzoquinone) and 4,4′-di[(3-methyl-6-tert-butyl-catecholato)triphenylantimony(V)]. The formed compounds react with each other returning the system into the initial state. Action of light of wavelength 313 and 405 nm on the initial reaction mixture leads to the formation of carbon monoxide, Ph3SbCatCatSbPh3 and the products of photolytic transformation of 4,4′-di(3-methyl-6-tert-butyl-o-benzoquinone).     

Effect of the β-substituent with respect to the azido group on the reactivity of methyl (2E)-3-[5-(azidomethyl)-2,2-diethyl-1,3-dioxolan-4-yl]-2-methylprop-2-enoate

Unlike methyl (2E)-3-[5-(azidomethyl)-2,2-diethyl-1,3-dioxolan-4-yl]-2—methylprop-2-enoate which is stable on storage, its acyclic derivative, methyl (2E,4S,5S)-6-azido-5-hydroxy-2-methyl-4-(pent-3-yloxy) hex-2-enoate at 20°C undergoes unusual decomposition with formation of exo-methylidenepyrrolidine. Analogous transformation was also observed in the epoxide ring opening in methyl (2E)-2-methyl-4-[(S)-oxiran-2-yl]-4-(pent-3-yloxy)but-2-enoate and in the substitution reaction of ethyl 5,6-bis(methanesulfonyloxy)-2-methyl-4-(pent-3-yloxy)hex-2-enoate with azide ion. Opening of the oxirane ring in the former by the action of azide ion was accompanied by formation of oxazetidine derivative as a minor product. The major intramolecular cyclization products, 4-hydroxy- and 4-mehtanesulfonyloxypyrrolidines were converted into stable pyrrole derivatives via elimination of the leaving groups. The hydrogenation of methyl and ethyl (2E)-3-[5-(azidomethyl)-2,2-diethyl-1,3-dioxolan-4-yl]-2-methylprop-2-enoates over palladium catalyst afforded the expected reduction products.     

Synthesis of 2-(ω-aminoalkyl)imidazolin-4-ones by ring chain transformation of lactam derivatives with α-aminoamides

Reaction of N-methylamides of biogenic (S)-α-amino acids 3 with lactam acetals 1 or lactim ethers 2 gives three types of products, i.e. N-methyl-α-lactamiminoamides 5 by condensation, 2-(ω-aminoalkyl)imidazolin-5-ones 7 or 2-(ω-lactamimmoalkyl)imidazolin-4-ones 8 by ring chain transformation. All products represent novel optically active derivatives of biogenic α-aminoacids.     

«3-Fluorisopren» (2-Fluor-3-methyl-1,3-butadien) und einige heterosubstituierte Abkömmlinge

‘3-Fluoroisoprene’ (2-Fluoro-3-methyl-1,3-butadiene) and Some Hetero-substituted Derivatives Thereof The readily accessible 1-chloro-1-fluoro-2-iodomethyl-2-methylcyclopropane undergoes zinc-promoted ring-cleavage yielding 2-fluoro-3-methyl-1, 3-butadiene (‘3-fluoroisoprene’) in almost quantitative yield. Alternatively the iodine atom may be replaced by electron-attracting groups such as cyano, benzenesulfonyl or triphenylphosphonio. Ring-opening of the resulting derivatives can then be brought about by various bases and leads to substituted fluorodienes. - The chemical reactivity of ‘3-fluoroisoprene’ has been studied in some detail. For example, it was found to add bromine at temperatures below 0° under kinetic control and to afford mainly the 1,4-adduct having the (Z)-configuration besides smaller quantities of the 1,2- and 3,4-adduct. At room temperature this mixture slowly undergoes a transformation yielding, as the sole products, both stereoisomeric 1, 4-adducts in a 1:1 ratio.     

Synthesis and cytotoxic activity of derivatives of the <Emphasis Type="Italic">tert</Emphasis>-butyl ester of 7<Emphasis Type="Italic">Z</Emphasis>-acetylmethylene-3-methyl-3-cephem-4-carboxylic acid

The condensation of the acetylmethylene group in the tert-butyl esters of 7Z-acetylmethylene-3-methyl-3-cephem-4-carboxylic acid and 7Z-acetylmethylene-3-methyl-1,1-dioxo-3-cephem-4-carboxylic acid and in 7Z-acetylmethylene-3-methylene-1,1-dioxo-3-cephem with arylmethoxyamines and O-alkylation of the tert-butyl ester of 7Z-(2-hydroxyimino)propylidene-3-methyl-1,1-dioxo-3-cephem-4-carboxylic acid using substituted benzyl bromides as well as pyridylmethyl chlorides gave arylmethoxyimino and pyridylmethoxyimino derivatives of these compounds in the syn and anti isomeric forms. The Vilsmaier reagent was used to introduce the N,N-dimethylaminomethylene group at C-2 of the cephem system in the tert-butyl esters of 7Z-[2-(arylmethoxyimino)propylidene]-3-methyl-1,1-dioxo-3-cephem-4-carboxylic acid. Subsequent transformation of the N,N-dimethylaminomethylene cephems using hydroxylamine led to 3Z-[2-(anti-arylmethoxyimino)propylidene]-tert-butoxycarbonylmethyl-4-(5-methyl-4-isoxazolylsulfonyl)- azetidin-2-ones. Condensation of the acetyl group in the tert-butyl ester of 7Z-acetylmethylene- 3-methyl-1,1-dioxo-3-cephem-4-carboxylic acid with 4-bromophenylhydrazine gave a cephem with a 2-(4-bromophenylhydrazono)propylidene group at C-7. Acylation of the tert-butyl ester of 7Z-(2-hydroxyimino)propylidene-3-methyl-1,1-dioxo-3-cephem-4-carboxylic acid by 2-bromobenzoyl chloride gave a cephem with a 2-(2-bromo-benzoyloxyimino)propylidene group at C-7. Biological screening of these products towards to malignant and normal cells in vitro showed that their antitumor activity and cytotoxic selectivity towards to malignant and normal cells depend on the structure and configuration of the arylmethoxyimino and pyridylmethoxyimino groups in the 7-alkylidene substituent as well as on the presence or absence of N,N-dimethylaminomethylene and carboxyl groups, respectively, at C-2 and C-4 of the cephem system.     

RING-TRANSFORMATION FROM ISOTHIAZOLE TO 1,2,4-THIADIAZOLE - POSSIBLE INTERMEDIACY OF π-SULFURANE

Abstract

5-Amino-3-methyl- and 5-amino-3-phenylisothiazoles (3a and 3b) afforded 1 : 1 adducts with aromatic nitriles and imidates. On the basis of their spectral data and the structure of hydrolysis products, the adducts were identified as 3-substituted 5-(2-aminovinyl)-1,2,4-thiadiazole derivatives (2a-g), where ring transformation took place from isothiazole to 1,2,4-thiadiazole.     

Synthesis of 2-(3-hydroxy-2-methyl-1-alkenyl)-1-pyrrolines and 2-(3-hydroxybutyl)-1-pyrroline using α-lithiated 2-methyl-1-pyrroline

Condensation of 2-methyl-1-pyrroline with chloroacetone or 3-chloro-2-butanone using LDA in THF afforded novel 2-(3-hydroxy-2-methyl-1-alkenyl)-1-pyrrolines via a peculiar reaction mechanism instead of the anticipated 2-(3-oxobutyl)-1-pyrrolines. The intermediacy of 2-(2,3-epoxy-2-methylalkyl)-1-pyrrolines in the latter transformation was demonstrated by immediate reductive epoxide ring opening utilizing lithium aluminium hydride in diethyl ether. Furthermore, 2-(3-oxobutyl)-1-pyrroline was prepared via an alternative approach through alkylation of 2-methyl-1-pyrroline with 3-chloro-2-(methoxymethyloxy)-1-propene using LDA in THF, followed by acid hydrolysis. Reduction of 2-(3-oxobutyl)-1-pyrroline by sodium borohydride in methanol afforded the corresponding 2-(3-hydroxybutyl)-1-pyrroline in good yield.     

Studies of the gas phase reactions of linalool, 6-methyl-5-hepten-2-ol and 3-methyl-1-penten-3-ol with O3 and OH radicals

The reactions of three unsaturated alcohols (linalool, 6-methyl-5-hepten-2-ol, and 3-methyl-1-penten-3-ol) with ozone and OH radicals have been studied using simulation chambers at T ～ 296 K and P ～ 760 Torr. The rate coefficient values (in cm(3) molecule(-1) s(-1)) determined for the three compounds are linalool, k(O3) = (4.1 ± 1.0) × 10(-16) and k(OH) = (1.7 ± 0.3) × 10(-10); 6-methyl-5-hepten-2-ol, k(O3) = (3.8 ± 1.2) × 10(-16) and k(OH) = (1.0 ± 0.3) × 10(-10); and 3-methyl-1-penten-3-ol, k(O3) = (5.2 ± 0.6) × 10(-18) and k(OH) = (6.2 ± 1.8) × 10(-11). From the kinetic data it is estimated that, for the reaction of O(3) with linalool, attack at the R-CH═C(CH(3))(2) group represents around (93 ± 52)% (k(6-methyl-5-hepten-2-ol)/k(linalool)) of the overall reaction, with reaction at the R-CH═CH(2) group accounting for about (1.3 ± 0.5)% (k(3-methyl-1-penten-3-ol)/k(linalool)). In a similar manner it has been calculated that for the reaction of OH radicals with linalool, attack of the OH radical at the R-CH═C(CH(3))(2) group represents around (59 ± 18)% (k(6-methyl-5-hepten-2-ol)/k(linalool)) of the total reaction, while addition of OH to the R-CH═CH(2) group is estimated to be around (36 ± 6)% (k(3-methyl-1-penten-3-ol)/k(linalool)). Analysis of the products from the reaction of O(3) with linalool confirmed that addition to the R-CH═C(CH(3))(2) group is the predominant reaction pathway. The presence of formaldehyde and hydroxyacetone in the reaction products together with compelling evidence for the generation of OH radicals in the system indicates that the hydroperoxide channel is important in the loss of the biradical [(CH(3))(2)COO]* formed in the reaction of O(3) with linalool. Studies on the reactions of O(3) with the unsaturated alcohols showed that the yields of secondary organic aerosols (SOAs) are higher in the absence of OH scavengers compared to the yields in their presence. However, even under low-NO(X) concentrations, the reactions of OH radicals with 3-methyl-1-penten-3-ol and 6-methyl-5-hepten-2-ol will make only a minor contribution to SOA formation under atmospheric conditions. Relatively high yields of SOAs were observed in the reactions of OH with linalool, although the initial concentrations of reactants were quite high. The importance of linalool in the formation of SOAs in the atmosphere requires further investigation. The impact following releases of these unsaturated alcohols into the atmosphere are discussed.     

Cyclization of 2-methoxy-6-(substituted benzyloxy)acetophenone hydrazones in the presence of polyphosphoric acid(PPA)

Cyclization of 2-methoxy-6-benzyloxy acetophenone hydrazone gave 3-methyl-4-meth-oxy indazole and 3-methyl-4-methoxy-7-benzyl indazole in the presence of polyphosphoric acid(PPA).The hydrazone was probably converted to 2-hydroxy-6-methoxy acetophenone hydra-zone and 2-hydroxy-3-benzyl-6-methoxy acetophenone hydrazone followed by cyclization to thecorresponding indazoles in acidic conditions.Cyelization of 2-methoxy-6-(halo or alkyl or arylbenzyloxy)acetophenone hydrazones gave similar products.Cyclization of 2-methoxy-6-(p-nitrobenzyloxy)acetophenone hydrazone gave 2-(p-nitrophenyl)-3-methyl-4-methoxy benzo-furan and 3-methyl-4-methoxy indazole while 2-methoxy-6-(m-nitrobenzyloxy)acetophenonehydrazone gave 3-methyl-4-methoxy indazole,3-methyl-4-methoxy-7-(m-nitrophenyl)indazole and3-methyl-4-(m-nitrobenzyloxy)indazole.     

Synthesis and Some Transformations of Ethyl 5-Alkoxymethyl-3-(2-methyl-3-oxobutyl)-2-oxotetrahydrofuran-3-carboxylates

Michael reaction of ethyl 5-alkoxymethyl-2-oxotetrahydrofuran-3-carboxylates with 3-methyl-3-buten-2-one gave ethyl 5-alkoxymethyl-3-(2-methyl-3-oxobutyl)-2-oxotetrahydrofuran-3-carboxylates. Alkaline hydrolysis of the latter, followed by decarboxylation afforded 5-alkoxymethyl-3-(2-methyl-3-oxobutyl)tetrahydrofuran-2-ones. The bromination of ethyl 5-alkoxymethyl-3-(2-methyl-3-oxobutyl)-2-oxotetrahydrofuran-3-carboxylates provides a convenient method for the preparation of 3-acetyl-8-alkoxymethyl-3-methyl- and 8-alkoxymethyl-3-bromoacetyl-3-methyl-2,7-dioxaspiro[4.4]nonane-1,6-diones in high yields.