二氯卡宾与甲醇及甲硫醇插入与氢抽提反应的量子化学计算

利用密度泛函和自然键轨道理论及电子密度拓扑分析方法，对单、三重态CCl2与CH3MH（M=O，S）中C—H和M—H键的插入反应及抽提氢反应进行了研究．在B3LYP／6-311G（d，p）水平上优化了势能面上构型，并以频率分析和内禀反应坐标法进行了确认．计算了各物种的CCSD（T）／6-211G（d，p）能量．结果表明，主反应通道主要发生在单重态势能面中，单重态CCl2既可以与C-H及M—H键发生插入反应，存在四条主反应通道，分别生成P1[CH3OCHCl2，反应Ⅰ（1）]，P3[Cl2HCCH2OH，反应Ⅰ（2）]和PS[CH3SCHCl2，反应Ⅱ（1）]，P7[Cl2HCCH2SH，反应Ⅱ（2）]，也可以与CH3MH发生抽提氢反应，分别生成P4[CH2O＋CH2Cl2，反应Ⅰ（3）]和P8[CH2S＋CH2Cl2，反应Ⅱ（3）]．同时，存在三重态CCl2与CH3SH插入生成^3P4[CH3SCHCl＋Cl]的反应通道．进一步对反应通道上的关键点进行了自然键轨道和电子密度拓扑分析．     

CH_3自由基和O（~3P）反应机理的量子化学研究

用分子轨道从头计算MP2（full）方法和密度泛函理论（DFT）中的B3LYP方法 研究了CH_3自由基和三线态O原子反应的微观机理，优化得到了反应途径上的反应 物、过渡态、中间体和产物的几何构型，通过振动分析对过渡态和中间体构型进行 了确认，在G3不平上计算了能量，同时用经典过渡态理论对该反应的绝对速率常数 进行了理论计算。研究结果表明：CH_3自由基与O（~3P）反应有四条不同的放热反 应通道，主反应通道为IM1→TS1→CH_2O + H，同时反应可彻底裂解生成CO, H_2 及H。     

CH3NO2与HE(23S)、Ne(3P0.2)的解离激发反应

利用分子束和化学发光技术，在单次碰撞条件下，首次研究了亚稳态原子He（23S）、Ne（3P0．2）与CH3NO2的解离激发反应，探测到反应的激发态产物（CH（A）、CH（B）、CH（C）的化学发光，在He（23S）／CH3NO2反应中同时探测到H（Balmer）的发射．利用He（23S）＋N2→N2＋（B）＋He＋e－作参考反应，测定了反应He（23S）／CH3NO2产生的CH的A－X，B－X，C－X以及H原子的发射速率常数．利用化学发光光谱的计算机模拟，求得了激发态产物CH（A）的初生态振动布居和转动温度．结合相空间理论对解离过程CH（A）的形成通道进行了讨论，认为CH（A）的形成是经由中间体CH3*的二体解离过程．     

硝酰氯和顺/反亚硝酸氯及其互变异构反应的理论研究

用密度泛函理论（DFT）的B3LYP方法和6－311＋G（3df）基组，计算了气态下硝酰氯和顺／反应硝酸氯的几何构型、电子结构、红外光谱以及热力学性质，并讨论了它们的互变异构反应，分析了过渡态的结构。结果表明，B3LYP／6－311＋G（3df）计算得到的结果与实验值及CCSD（T）方法计算结果吻合，且更适应于研究反应机理，ClNO2转变为cis-ClONO的过渡态（TS1）偏离平面构型；cis-ClONO和trans-ClONO互变反应的过渡态（TS2）属于内旋转位垒；高水平计算表明不存在由ClNO2直接转变为trans-ClONO的过渡态，而是得到了一个十分接近异裂产物的二级马鞍点（2SP）。根据得到的热力学函数计算了气态时各温度下互变异构反应的平衡常数。     

2,2'－联吡啶桥连的双－4,4'-联吡啶哑铃型化合物的合成

二甘醇2与对甲苯磺酰氯在CH_2Cl_2中，0 ℃～r.t.及Et_3N存在下反应得2－ （羟乙氧基）乙醇对甲苯磺酸酯（3），收率88％。化合物3与对叔丁基苯甲酰氯在 CH_2Cl_2中0～5 ℃及吡啶存在下反应得2－（对叔丁基苯甲酰氧基乙氧基）乙醇对 甲苯磺酸酯（4），收率96％。4与对羟苯甲醇在乙腈中及CsF/K_2CO_3存在下70 ℃ 反应得2－（对叔丁基苯甲酰氧基乙氧基）乙氧苄醇（5），收率98％。5与NBS及 PPh_3在THF中，室温下反应得化合物2－（对 丁基苯甲酰氧基乙氧基）乙氧苄溴 （6），收率95％。6与4,4'－联吡啶在乙腈中，60 ℃反应1h得N－[2－（对叔丁基 苯甲酰氧基乙氧基）乙氧苄基]－4,4'－联吡啶六氟磷酸盐（7），收率85％。7与 α,α－二（溴甲基）－2,2'－联吡啶在乙腈中，油浴60 ℃反应36h，得到标题化 合物，产率为45％。     

CH4+O(3P)→CH3+OH反应的准经典轨线研究

用准经典轨线方法研究了O（3P）与CH4的反应，计算结果表明，CH4（υ＝0，j＝0）与O（3P）的反应在低及高的碰撞参数下都是直接反应，无短寿命的碰撞复合物生成，产物OH以向后散射为主，基本上处于振转基态.CH4（υ＝1，j＝1）与O（3P）的反应在低及高的碰撞参数下反应机理不一样。在低碰撞参数下是直接反应，无短寿命的碰撞复合物生成，产物OH以向后散射为主，主要处于振动基态，转动基本上是冷的，但比高碰撞参数下的热.在高的碰撞参数下则生成短寿命的碰撞复合物，产物OH以向前散射为主，表现出明显的周边动力学反应的特征，主要处于振动激发态（υ＝1），但转动仍然是较冷的。     

三价铁离子与硫离子反应的实验探究

探究了水溶液中Fe3+与S2-的反应，得出几点结论：生成Fe2S3的沉淀反应是动力学优势反应，生成Fe2+和S的氧化还原反应是热力学优势反应；发现Fe2S3可以与Fe3+反应生成S和Fe2+，Fe2S3在酸性条件下不稳定；在弱碱性条件下，Fe3+也有与HS-发生氧化还原反应的倾向；Fe3+在水溶液中主要以水解产物[Fe（H2O）6-n（OH）n]（3-n）+（n=1，2）存在，[Fe（H2O）6-n（OH）n]（3-n）+的氧化性很弱，难以将H2S或HS-氧化，却易与S2-结合生成Ksp极小的Fe2S3沉淀。     

Br+CH3S(O)CH3反应机理的直接动力学研究

采用直接动力学的方法，对多通道反应体系Br＋CH3S（O）CH3进行了理论研究．在BH＆H-LYP／6-311G（2d，2p）水平下获得了优化几何构型、频率及最小能量路径（MEP），能量信息的进一步确认在MC-QCISD（单点）水平下完成．利用正则变分过渡态理论，结合小曲率隧道效应校正（CVT／SCT）方法计算了该反应的两个可行的反应通道在200K～2000K温度范围内的速率常数．在整个反应区间内，生成HBr的反应通道与生成CHa的反应通道存在着竞争，前者是主反应通道，后者是次反应通道．变分效应和小曲率隧道效应对反应速率常数的计算影响都很小．理论计算得到的两个反应通道的反应速率常数与实验值符合得很好．     

O（~1D）与CF_2HCl反应的理论研究

用量子化学密度泛函理论（DFT）和G3B3方法，对为（~1D）与CF_2HCl的反应 进行了研究，在B3LYP/6-311+G(d)，B3LYP/6-311+G(2df,2pd)和G3B3计算水平上， 优化了反应热能面上各驻点的几何结构，通过内禀反应坐标（IRC）计算和振动分 析，对反应过渡态进行了确认，并确定了反应机理。     

异戊二烯催化脱氢环氧化的研究

 合成了钼－乙酰丙酮配合物，并进行了表征，确定了其组成为M\r\noO2（acac）2．以MoO2（acac）2为催化剂，以过氧化氢为氧化剂，对\r\n异戊二烯一步脱氢环氧化制3－甲基呋喃反应进行了研究．考察了反应\r\n条件（催化剂用量、反应底物之比、温度、时间、溶剂和助剂等）对该\r\n反应的影响．结果表明，在n（cat）∶n（CH2∶C（CH3）CH∶CH2）∶\r\nn（H2O2）＝1∶100∶100，θ＝40℃，t＝6h的反应条件下，异戊二烯\r\n转化率为70．8％，3－甲基呋喃选择性为54．8％．提出了异戊二烯脱\r\n氢环氧化可能的反应机理．     

合成1,2-环十二二酮的新方法

以十二烷二酸（１）为原料,与甲醇酯化生成十二烷二酸二甲酯（２）,收率为８６５％。化合物２经偶联 缩合得１,２ 二三甲基硅氧基环十二烯（３）,收率为６３１％。利用溴氧化化合物３得到１,２ 环十二二酮（４）淡黄色晶体,收率７９％,全过程收率达４３.１％,是合成１,２ 二酮的新方法。目标化合物结构经红外光谱、核磁共振氢谱和碳谱表征确认。     

A Carbohydrate Approach to the Enantioselective Synthesis of 1,3-Polyols

Treatment of per-O-benzoyl-D-glycero-D-gulo-heptono-1,4-lactone (2) with tertiary amines afforded selectively and with good yields the (5H)-furan-2-one derivatives 3, 4, and 5, formed by controlled elimination of one, two, or three molecules of benzoic acid, respectively. The stereochemistry for the exocyclic double bonds of 4 and 5 was determined by means of NMR techniques. Particularly, the furanone 4 was obtained from 2 ( approximately 90% yield) as a mixture of the E and Z diastereoisomers, which were separated by column chromatography or, more efficiently, by HPLC. The catalytic hydrogenation of compounds 4-E and 4-Z took place diastereoselectively, due to the chiral induction of the stereocenter located in the lateral chain. Thus, hydrogenation of 4-E led to a mixture of the 4,5-dihydro-(3H)-furan-2-ones having 3R,5S,2'S (D-xylo, 6) and 3S,5R,2'S (D-arabino, 7) configurations, with 6 as the major product; whereas the 4-Z isomer gave the same mixture, but being 7 preponderant. On hydrogenation of the original 4-E/Z mixture, compound 6 was obtained pure after recrystallization. O-Debenzoylation of 6gave 9, which was reduced with NaBH(4) to the 3,5-dideoxy-meso-xylo-heptitol (11). The peracetate (12) and perbenzoate (13) of the latter were prepared, and the 1-(tert-butyldiphenylsilyl)oxy derivative (16) was also synthesized via the 3'-(silyloxy)-4,5-dihydro-(3H)-furan-2-one 14. Chemoselective reduction of the lactone function of 6 with diisoamylborane gave the 2,5,6-tri-O-benzoyl-3,6-dideoxy-D-xylo-heptofuranose (17). The 3,5-dideoxy-D-arabino-heptitol (18), a diastereoisomer of 11, was also isolated and characterized.     

Improved synthesis and molecular modeling of 4beta,19-dihydroxyandrost-5-en-17-one,an excellent inhibitor of aromatase

4Beta,19-dihydroxyandrost-5-en-17-one (6) is an excellent competitive inhibitor of estrogen synthetase (aromatase). Alternate, improved synthesis of this inhibitor was established. Treatment of 19-(tert-butyldimethylsilyloxy)androst-4-en-17-one (8) with m-chloroperbenzoic acid gave a 1.4:1 mixture of 4alpha,5alpha-epoxide 9 and its 4beta,5beta-isomer 10. The mixture was reacted with diI. HClO4 in dioxane to produce principally 4beta,5alpha-diol 11 (80%) of which acetylation followed by dehydration with SOCl2 yielded 4beta,19-diacetoxy-5-ene compound 14 in good yield. Alkaline hydrolysis of diacetate 14 gave 4beta,19-diol 6. The minimum energy conformation of the powerfull aromatase inhibitor 6 was obtained with the PM3 method and compared with that of the structurally related diol steroid, 4-ene-5beta,19-diol 3, a weak competitive inhibitor.     

5-Pyrimidylboronic acid and 2-methoxy-5-pyrimidylboronic acid: new heteroarylpyrimidine derivatives via Suzuki cross-coupling reactions

5-Pyrimidylboronic acid and 2-methoxy-5-pyrimidylboronic acid 4 have been synthesised by lithium-halogen exchange reactions on 5-bromopyrimidine and 2-methoxy-5-bromopyrimidine, respectively, followed by reaction with triisopropylborate. Suzuki cross-coupling reactions of 2 and 4 with heteroaryl halides [Na(2)CO(3), Pd(PPh(3))(2)Cl(2), 1,4-dioxane, 95 degrees C] yield heteroarylpyrimidines (heteroaryl = thienyl, quinolyl and pyrimidyl). Two-fold reaction of 2 with 4,6-dichloropyrimidine 12 gave 4,6-bis(5-pyrimidyl)pyrimidine 8(56% yield). Reaction of 4,6-dichloropyrimidine with 2-methoxy-5-pyridylboronic acid gave 4,6-bis(2-methoxy-5-pyridyl)pyrimidine 14 (84% yield). Conversion of into 4,6-bis(2-chloro-5-pyridyl)pyrimidine 15 (63% yield) followed by two-fold Suzuki reaction with 4-tert-butylbenzeneboronic acid gave the penta-arylene derivative 4,6-bis[2-(4-tert-butyl)phenyl-5-pyridyl]pyrimidine 16 (16% yield). Analogous reaction of 12 with 2-methoxy-3-pyridylboronic acid 17 gave 4,6-bis(2-methoxy-3-pyridyl)pyrimidine 18 (64% yield). The X-ray crystal structures of compound 2.0.5H(2)O and compound 18 are reported. The two hydroxyl H atoms in 2 have the usual exo-endo orientation. However, unlike most arylboronic acids, molecule 2 does not form a centrosymmetric hydrogen-bonded dimer. In molecule 18, the pyridine rings form dihedral angles of 39.9 degrees and 22.8 degrees with the central pyrimidine ring.     

梨小食心虫性信息素的新法合成

梨小食心虫 (Grapholia molesta)是一种世界性果树害虫 ,主要危害梨、桃和苹果等果树 . 1 96 5年Geroge等 [1] 从该雌蛾腹部分离得到其性信息素 . 1 96 9年 Roelofs等 [2 ] 鉴定其结构为 8(Z/E) -十二碳烯 - 1 -醇乙酸酯 (6 ) .国内外对其生物活性进行了大面积田间试验 ,并用于     

Epoxidation and reduction of DHEA, 1,4,6-androstatrien-3-one and 4,6-androstadien-3beta,17beta-diol

Dehydroepiandrosterone (DHEA) reacted with m-chloroperoxybenzoic acid(m-CPBA) to form 3beta-hydroxy-5alpha,6alpha-epoxyandrostan-17-one (1), but it did not react with 30% H2O2. 1,4,6-Androstatrien-3,17-dione (2) was obtained from DHEA and 2,3-dichloro-5,6-dicyano-1,4-benzoquinone in dioxane. Compound 2 was reacted with 30%H2O2 and 5% NaOH in methanol to give 1alpha,2alpha-epoxy-4,6-androstadien-3,17-dione (3),which was stereoselectively reduced with NaBH4 to form 1alpha,2alpha-epoxy-4,6-androstadien-3beta,17beta-diol (7) and reacted with Li metal in absolute ethanol-tetrahydrofuran mixture to give 2-ethoxy-1,4,6-androstatrien-3,17-dione (8). Compound 2 was also epoxidized with m-CPBA in dichloromethane to afford 6alpha,7alpha-epoxy-1,4-androstadien-3,17-dione (4),which was reacted with NaBH4 to synthesize 6alpha,7alpha-epoxy-4-androsten-3beta,17beta-diol (9).Compound 4 was reduced with Li metal in absolute ethanol-tetrahydrofuran mixture to form 7beta-ethoxy-6alpha-hydroxy-1,4-androstadien-3,17-dione (10). Compound 2 was reduced with NaBH4 in absolute ethanol to form 4,6-androstadien-3beta,17beta-diol (5), which was reacted with 30% H2O2 to give the original compound, but which reacted with m-CPBAto give 4beta,5beta-epoxy-6-androsten-3beta,17beta-diol (6).     

(Z)-3-丁烯基-5-羟基苯酞的合成

以对羟基苯甲酸为原料,首次合成(Z)-3-丁烯基-5-羟基苯酞．发现芳环上的甲胺甲酸基中氮原子的诱导作用是关键步骤,使甲胺甲酸基邻位选择性理化,从而在芳环上定向引入甲酸基．     

5α,11-二羟基-2-氧代桉烷-3-烯的全合成

5α，11-二羟基-2-氧代桉烷-3-(5α-Hydroxy—isopterocarpolone，1)是由贾忠建等于1996年从中药南牡蒿中首次分离得到的一种桉烷型倍半萜类天然产物．桉烷型倍半萜类化合物广泛分布于天然植物中，具有较好的昆虫拒食、抑制细胞繁殖和植物生长调节等多种生理活性．天然产物1的合成研究尚未见报道．     

三种保护的二糖苯丙素苷的合成研究

本文采用先成苷法，从已合成的2-对烯丙氧苯乙基-4,6-O-亚苄基-β-D-葡萄糖苷(1)出发，经2位选择性乙酰化、3位引入三乙酰基保护的鼠李糖基、4，6位脱去亚苄基，得到了关键的中间体4；在化合物4的葡萄糖4、6位分别引入对位取代的肉桂酰基，便得到了保护的二糖苯丙素苷5、7、8。与后成苷法相比，路线缩短一步，收率有所提高。     

Syntheses of substituted 1-methyl-2-(1,3,4-thiadiazol-2-yl)-4-nitropyrroles and 1-methyl-2-(1,3,4-oxadiazol-2-yl)-4-nitropyrroles

Starting from readily available ethyl-4-nitropyrrole-2-carboxylate ( 1 ), substituted 1-methyl-2-(1,3,4-thiadiazol-2-yl)-4-nitropyrroles and 1-methyl-2-(1,3,4-oxadiazol-2-yl)-4-nitropyrroles were prepared. The reaction of 1 with diazomethane gave ethyl 1-methyl-4-nitropyrrole-2-carboxylate ( 2 ). Reaction of compound 2 with hydrazine hydrate afforded the corresponding hydrazide 3 . The reaction of 3 with formic acid yielded 1-(1-methyl-4-nitropyrrole-2-carboxyl)-2-(formyl)hydrazine ( 7 ). Refluxing of the latter with phosphorus pentasulfide in xylene yielded compound 6 in 40% yield. Reaction of compound 7 with phosphorus pentoxide afforded compound 9 . Reaction of compound 3 with 1,1′-carboxyldiimidazole in the presence of triethylamine yielded 2-(1-methyl-4-nitro-2-pyrrolyl)-1,3,4-oxadiazoline-4(H)-5-one ( 11 ). Refluxing compound 3 with cyanogen bromide in methanol gave compound 12 . Compound 13 could be obtained through the reaction of compound 3 with carbon disulfide in basic medium. Alkylation of compound 13 afforded the correspanding alkylthio derivative 14 . Reaction of 1-methyl-4-nitropyrrole-2-carboxylic acid ( 15 ) with thiosemicarbazide and phosphorus oxychloride gave 2-amino-5-(1-methyl-4-nitro-2-pyrrolyl)-1,3,4-thiadiazole ( 16 ). Sandmeyer reaction of compound 16 yielded 2-chloro-5-(1-methyl-4-nitro-2-pyrrolyl)-1,3,4-thiadiazole ( 17 ). Refluxing of the latter with thiourea afforded 2-(1-methyl-4-nitro-2-pyrrolyl)-1,3,4-thiadiazoline-4(H)-5-thione ( 18 ). Alkylation of compound 18 gave the corresponding alkylthio derivative 19 . Oxidation of the latter with hydrogen peroxide in acetic acid yielded 2-(1-methyl-4-nitro-2-pyrrolyl)-5-methylsulfonyl-1,3,4-thiadiazole ( 20 ).