5,7-二甲氧基-4-甲基苯酞和5,7-二羟基-4-甲基苯酞的新合成方法

以3,5-二甲氧基苯甲醇为起始原料, 经过五步反应, 合成了5,7-二甲氧基-4-甲基苯酞和5,7-二羟基-4-甲基苯酞这两个用于合成霉酚酸的重要中间体, 产率分别达到80%和72%. 6-氯甲基-2,4-二甲氧基苯甲醛经过亚氯酸钠氧化成酸的同时发生内酯化反应生成5,7-二甲氧基苯酞是最关键的一步.     

取代二氢异喹啉基苯基甲基酮的合成新方法

以3,4-二甲氧基苯乙酸为原料,经氯化亚砜酰氯化、3,4-二甲氧基苯乙胺氨解得到了N-(3,4-二甲氧基苯乙基)-2-(3,4-二甲氧基苯基)乙酰胺,经Bischler-Napieraski反应环化同时氧化,合成了Lamellarin重要中间体(6,7-二甲氧基-3,4-二氢异喹啉-1-基)(3,4-二甲氧基苯基)甲基酮,优化了环化的反应条件,其总收率为56%。此方法未见文献报道。产物用1H NMR、13C NMR、MS、IR进行了表征。     

5-羟基嘧啶——Ⅴ.1,3-二甲氧基乙酰丙酮与胍和硫脲的缩合

1,3-二甲氧基乙酰丙酮(1)与胍在中性条件下以低产率(28%)缩合生成5-甲氧基-2-氨基-6-甲氧甲基-4-甲基嘧啶(3),而不与硫脲缩合。在与S-甲基异硫脲的反应中,1降解为甲氧基丙酮和甲氧基乙酸,从而生成甲氧基丙酮缩-S-甲基异硫脲甲氧基乙酸盐(4)和S-甲基异硫脲甲氧基乙酸盐(5)。由此可见,1对碱非常敏感,而对酸有一定的稳定性。     

二代螺环树形化合物1,2,3,4,5,6,7,8,9,10,11,12-十二氢-2,2;6,6;10,10-三[3,3-二(烷氧羰基)-1,1-环亚丁基二甲氧基]三亚苯基的合成

以1,4-环己二酮、丙二酸二乙酯及多元醇等为原料, 经过两次“一锅煮”法合成了六种二代螺环树形化合物1,2,3,4,5,6,7,8,9,10,11,12-十二氢-2,2;6,6;10,10-三[3,3-二(烷氧羰基)-1,1-环亚丁基二甲氧基]三亚苯基螺环树形化合物, 其中烷氧基为异戊氧基、三羟甲基甲氧基、2,2-二溴甲基-3-羟丙氧基、2,2-二羟甲基丙氧基、二羟甲基膦甲氧基和(N-羟甲基-N-二羟甲基氨基乙基)甲氧基. 利用IR, NMR, MS和元素分析对合成的化合物进行了结构认证, 对影响反应的因素进行了讨论.     

5-甲基-7-甲氧基异黄酮的合成

5-甲基-7-甲氧基异黄酮的合成;二羟基甲基脱氧安息香; 甲基甲氧基异黄酮; 二羟基甲苯; 有机合成     

水介质中9,10-二芳基吖啶的洁净合成

水介质中在十二烷基磺酸钠(SDS)催化下, 席夫碱与双甲酮反应合成了一系列9,10-二芳基吖啶衍生物, 同时分离得到一种中间产物. 所有产物的结构通过红外光谱和1H NMR光谱确定, 产物10-(4-氯苯基)-9-(4-甲氧基苯基)-3,3,6,6-四甲基-3,4,6,7,9,10-六氢化吖啶-1,8(2H,5H)-二酮(3i)和中间产物2-{4-氯苯基-[2-(4-甲氧基苯基氨基)-4,4-二甲基-6-氧代环已-1-烯基]甲基}-3-羟基-5,5-二甲基环已-2-烯酮(4h)的结构还通过单晶X射线衍射分析确证.     

1,3-二烷氧基-乙酰丙酮和-丙酮的[1,3] 键迁移重排

1,3-二甲氧基-2-吗啉-N-基戊1-烯-4-酮(11a)的酸水解经证实发生部分重排, 生成1,3-(1a)和1,5-二甲氧基乙酰丙酮(2a)的混合物, 并通过与氰基乙酰胺缩合, 分别形成3-氰基-4-甲氧甲基-5-甲氧基-6-甲基吡啶-2-醇(3a)和3-氰基-4,6-双(甲氧甲基)吡啶-2-醇(4a)加以证实, 前者还转化为维生素B6. 在相应的乙氧基序列中, 除得到1b丶2b丶3b和4b外, 还分离了反向缩合产物3-氰基-4-甲基-5-乙氧基-6-乙氧甲基吡啶-2-醇(5b) . 对Fedoronko 等为1,3-二甲氧基丙酮的重排-水解为丙酮醛提出的烯丙型重排机制提出了质疑. 事实上, 这一重排更可能是一利热过程的[1.3]单键迁移过程和提供了支持的事例.     

由2'''',4''''-二氢-6''''-甲氧基-3'''',5''''-二甲基查耳酮合成新黄酮

在DMSO/ I2的氧化作用下,由2',4'-二氢-6'-甲氧基-3',5'-二甲基查耳酮可合成一种全新结构的黄酮:7-羟基-5-甲氧基-6,8-二甲基黄酮(产率91%),而在HCl/MeOH作用下则得到了两种黄烷酮:7-羟基-5-甲氧基-6,8-二甲基黄烷酮 (产率70%) 和 5,7-二羟基-6,8-二甲基黄烷酮 (产率20%).     

二苯乙烯衍生物的合成及抗肿瘤活性

以甲氧基取代的4’-氨基二苯乙烯与4-溴甲基-5-甲基-1,3-二氧杂环戊烯-2-酮为原料,通过亲核取代反应合成得到了4种新的二苯乙烯衍生物。这些化合物的结构经NMR、IR和元素分析确定。以HeLa、SMMC-7721、BGC-823和A549为受试细胞株,用MTT法测试了这4种化合物的抗肿瘤活性。测试结果表明,这些化合物具有一定的抗肿瘤活性。     

由2′,4′-二氢-6′-甲氧基-3′,5′-二甲基查耳酮合成新黄酮

在DMSO/I2的氧化作用下,由2′,4′-二氢-6′-甲氧基-3′,5′-二甲基查耳酮可合成一种全新结构的黄酮:7-羟基-5-甲氧基-6,8-二甲基黄酮(产率91%),而在HCl/MeOH作用下则得到了两种黄烷酮:7-羟基-5-甲氧基-6,8-二甲基黄烷酮(产率70%)和5,7-二羟基-6,8-二甲基黄烷酮(产率20%)。     

用离子阱经H2++H2碰撞反应碰撞反应制备H4+

用Penning型离子阱经碰撞反应H2++H2→H4+产生稳定的H4+。主要的反应产物是H3+,但十分明显地观测到H4+信号。H4+在阱中稳定存在时间长达0.1s量级。远比Kirchner等人测量的10-6s量级长。最后讨论了生成H4+的反应过程机制。     

Chemical composition and possible in vitro antigermination activity of three Hypericum essential oils

The essential oils of Hypericum perforatum, H. perfoliatum and H. hircinum, growing in Southern Italy, were analyzed by GC and GC/MS. In the three oils, 111 compounds in all were identified: 53 for the oil of H. hircinum (93.7% of the total oil), 55 for H. perforatum (96.5% of the total oil) and 63 for H. perfoliatum (98.7% of the total oil). The major fraction of the essential oils of H. perforatum and H. hircinum was represented by sesquiterpene hydrocarbons, while the monoterpene alpha-pinene, and the phenol thymol were the most abundant compounds in the essential oil of H. perfoliatum. The oils were evaluated for their potential in vitro phytotoxic activity against germination and early radicle elongation of Raphanus sativus and Lepidium sativum. The germination of this latter was significantly inhibited by the essential oil of H. hircinum, at the highest doses tested, whereas radicle elongation of garden cress was significantly inhibited by the essential oils of H. perfoliatum and H. hircinum. The radicle elongation of radish was inhibited by the essential oil of H. hircinum to a major extent and by H. perforatum and perfoliatum in a minor measure.     

在水-四氢呋喃中纤维素转化为5-羟甲基糠醛及副产物鉴定

在酸性条件下,水-四氢呋喃混合溶剂中转化纤维素制备了平台化合物5-羟甲基糠醛（HMF）．在纤维素浓度仅为2.4wt%时,可以得到38.6%的HMF,但是随着纤维素浓度的增加,胡敏素和乙酰丙酸成为主要产物．利用液相色谱-多级串联质谱联用技术检测到了分子式为C9H16O4、 C10H14O4、 C11H12O4、C12H10O5 和C12H16O8的一系列副产物．C9H16O4是通过四氢呋喃开环为1,4-丁二醇再与乙酰丙酸酯化反应得到,而C10H14O4是通过四氢呋喃开环后与HMF醚化得到．C11H12O4是由5-羟甲基糠醛与乙酰丙酸发生酯化反应得到,C12H10O5是由HMF自身醚化得到,而C12H16O8是HMF与葡萄糖经过缩醛反应得到．HMF的自身醚化反应及HMF与1,4-丁二醇的醚化反应是主要的副反应．     

重水中固氮酶催化还原乙炔产物的^1H NMR研究

用^1HNMR研究了固氮酶在重水中催化还原乙炔的反应产物氘代乙烯.种用群对称性对^1HNMR谱图进行了归属,计算了几种可能的C`2H~2D~2结构以及C~2H~3D结构的NMR谱线频和强度,得出了理论谱.通过理论谱与实验谱的比较,表明固氮酶在重水中催化还原乙炔的产物主要以顺式结构C~2H~2D~2为主,并含有较多的单氘代烯.单氘代乙烯相对乙烯的化学位移往高场移动约4.0Hz,而双氘代乙烯向高场的位移大约是单氘代乙烯的2倍左右。     

Impact of growth kinetics on morphology and pore structure of TiO2-one-pot synthesis of macroporous TiO2 microspheres

Titanium dioxide was synthesized by the hydrolysis of titanium tetraisopropoxide (TTIP) in the presence of acetic acid, 2-propanol, and organic amines (octylamine, aniline, and isobutylamine). H2O was supplied by an esterification reaction between acetic acid and 2-propanol (denoted as H2Oe), and/or by intentionally adding it (denoted as H2Oa). It was found that the quantity of H2Oa plays a crucial role in the morphology and porous structure of the final TiO2 product. Without the addition of H2Oa, 1D and porous TiO2 was synthesized. With the addition of H2Oa, and when the H2Oa:TiO2 molar ratio was in the range of 1:1 to 60:1, macroporous TiO2 microspheres possessing a large surface area and high thermal stability were obtained. When the H2Oa:TiO2 molar ratio exceeded 60:1, porous TiO2 with an irregular shape was formed. The variation in the morphology and porous structure is attributed to the manipulation of the growth kinetics by the addition of water.     

Mechanistic study of thermal decomposition of isoprene (2-methyl-1,3-butadiene) using flash pyrolysis supersonic jet VUV photoionization mass spectrometry

The thermal decomposition of isoprene up to 1400 K was performed by flash pyrolysis with an approximately 100 mus time scale. This pyrolysis was followed by supersonic expansion to isolate the reactive intermediates and initial products, and detection was accomplished by vacuum ultraviolet single photon ionization time-of-flight mass spectrometry (VUV-SPI-TOFMS) at lambda = 118.2 nm. Products CH(3), C(2)H(4), C(3)H(3), C(3)H(4), C(4)H(4), C(4)H(5), C(5)H(6), C(5)H(7), and C(6)H(6) were directly observed and provide mechanistic insights to the isoprene pyrolysis. At temperatures >or= approximately 1200 K, the molecular elimination of ethene to form C(3)H(4) and sigma bond homolysis producing C(4)H(5) and CH(3) radicals are competitive reaction pathways. The molecular elimination of acetylene to form C(3)H(6) was minimal and direct C(2)-C(3) sigma bond homolysis was not observed. The C(3)H(3) radicals are also observed, as a result of hydrogen loss of C(3)H(4) by pyrolysis or hydrogen abstraction by the CH(3) radical from C(3)H(4). Above approximately 1250 K, production of C(6)H(6) was observed and identified as the combination product of the C(3)H(3) radicals.     

Ab initio molecular dynamics simulation of the energy-relaxation process of the protonated water dimer

Relaxation processes of the energy-rich protonated water dimer H+(H2O)2 were investigated by the ab initio molecular dynamics (AIMD) method. At first, the energy-rich H+(H2O)2 was reproduced by simulating a collision reaction between the protonated water monomer H3O+ and H2O. Next it was collided with N2 in order to observe the effects of intramolecular vibration redistribution and intermolecular energy transfer. Forty-eight AIMD simulations of the collision of H+(H2O)2 with N2 were performed by changing the initial orientation and the time interval between two collisions. It was revealed that the amount of energy transferred from H+(H2O)2 to N2 decreased the longer the time interval. The relationship between the intermolecular energy transfer and the vibrational states was examined with the use of an energy-transfer spectrogram (ETS), which is an analysis technique combining energy density analysis and short-time Fourier transform. The ETS demonstrates a characteristic vibrational mode for the energy transfer, which corresponds to the stretching of the hydrogen bond between H+(H2O)2 and N2 in an active complex.     

Mechanism of phosphine photolysis. Application to Jovian atmospheric photochemistry

PH3 is photolyzed to H2 and P2H4 and the P2H4 in turn is converted to red phosphorus. The initial quantum yield of H2 formation was redetermined and found to be 0.93 +/- 0.07. Red phosphorus was identified by its chemical properties and the absence of P-H stretching bands in its infrared spectrum. The reaction pathway was not changed by lowering the PH3 partial pressure from 90 to 11 torr or by performing the photolysis in a 70-fold excess of H2. The initial quantum yields at 11 torr of PH3 are phi P2H4 = 0.04 +/- 0.02 and phi H2 = 0.74 +/- 0.08. The initial rate of P2H4 formation was not affected by lowering the PH3 temperature to 227 or 157 K. The yield was greater at 157 K because the P2H4 condensed and was protected from further destruction. The initial quantum yields for the formation of P2H4 and H2 in PH3-NH3 mixtures were comparable to those observed for PH3 alone. Photolysis of mixtures in which NH3 was absorbing 90% of the light resulted in the rapid formation of P2H4. No N2 was formed when PH3-NH3 mixtures were photolyzed, suggesting that the destruction of NH3 is quenched by PH3. The application of these findings to Jovian atmospheric chemistry is discussed.     

对当量为1的预混乙烯/氧气/氩气火焰的实验研究

A comprehensive experimental study of the premixed ethylene/oxygen/argon flame at 2.667 kPa with a stoichiometric equivalence ratio (φ=1) was performed with the tunable synchrotron photoionization and molecular-beam sampling mass spectrometry techniques. The isomers of most observed species in the flame were unambiguously identified by measurements of the photoionization efficiency spectra, e.g. C3H4, C2H4O and C4H4. The mole fraction profiles of species up to C7H8 were measured by scanning the burner position at the selected photon energies near ionization thresholds, and the flame temperature profile was obtained by using Pt/Pt-13%Rh thermocouple. Compared with the previous studies, a lot of new flame species:C3H2, C3H3, C3H5, C2H6O, C4H2, C4H4, C4H6, C3H4O, C3H6O, C3H8O, C5H6, C4H8O and C7H8, were observed. A series of free radicals in the flame are detected to be CH3, C2H3, C2H5, HCO, C3H3 and C3H5.Based on the experimental work, a reduced reaction mechanism was developed including 40 species and 223 reactions. Modeling and measurements agree well for the major species and most intermediates. A detailed kinetic model is desired for this flame.