一测多评方法应用于高效液相色谱法测定防晒产品中15种防晒剂的含量

选用CAPCELL PAK C18色谱柱为分离柱,柱温为30℃,进样体积为10.0μL,并用不同比例的(A)甲醇、(B)四氢呋喃和(C)0.008 2mol·L^-1高氯酸溶液的混合液作为流动相,按程序梯度洗脱模式对市售防晒产品中所用的15种防晒剂的标准品进行色谱分离,并在波长311nm处进行紫外检测。实样分析时,称取样品0.25g,用甲醇、四氢呋喃、水和高氯酸(体积比为250∶450∶300∶0.2)的混合液(以下简称混合溶剂)15 mL超声提取30 min,用混合溶剂定容至25.0mL,离心10min,分取上清液1.0mL,加入混合溶剂定容至10.0mL,经0.45μm滤膜过滤,取滤液按仪器工作条件进行高效液相色谱分析。结果表明:所测定的15种防晒剂在一定的质量浓度范围内与其对应的峰面积呈线性关系。选定其中的二苯酮-3为参照物,并根据其余14种化合物的质量浓度和峰面积计算了各化合物的相对校正因子和相对保留时间等参数,确定了用一测多评法(QAMS)测定防晒产品中15种防晒剂的条件。还对色谱柱的型号、色谱仪器的型号以及柱温、进样量等对相对校正因子和保留时间可能产生影响的因素进行了系统试验。证明了在选定的色谱柱型号的前提下,用QAMS方法可实现防晒产品中15种防晒剂含量的同时测定。应用QAMS方法测定了6个批次防晒产品中的防晒剂含量,所得结果与用标准曲线法计算的结果基本一致,表明QAMS方法在降低检测成本和节省检测时间方面效果显著。     

注入Y离子对Ni3Al合金高温氧化行为的影响

以40 KeV的能量和3×1017 /cm2的剂量在Ni3Al合金中注入Y离子, 利用热重分析、 X射线衍射、扫描电镜、能谱分析和划痕分析等技术研究了离子注入对其900 ℃恒温氧化行为的影响. 结果表明 注入Y离子不仅改变了合金的氧化动力学, 而且改变了其氧化机理. 注入Y离子后合金氧化产物中的NiO含量大为增加, 从而降低了合金的抗氧化性能. 但Y离子的注入使NiO晶粒细化, 增强了氧化膜的塑性和粘附性.     

(R)-2-羟基-4-苯基丁酸乙酯的合成

综述了血管紧张素转化酶抑制剂类治疗高血压和充血性心力衰竭药物的关键中间体（R）－2－羟基－4－苯基丁酸乙酯的合成方法。参考文献25篇。     

新型蒈酸基双酰肼化合物的合成及其生物活性

先将3-蒈烯分子中的碳碳双键氧化开环制得蒈酮酸，再将羰基还原成亚甲基得到蒈酸，酰氯化后与系列酰肼发生N-酰化反应合成了14个新型蒈酸基双酰肼化合物(5a～5n)，其结构经UV-Vis、¹H NMR、¹³C NMR、 FT-IR和MS(ESI)表征，并测试了目标化合物的抑菌和除草活性。结果显示：在用药量为50 μg·mL^-1时，目标化合物对花生褐斑病菌、小麦赤霉病菌、黄瓜枯萎病菌、苹果轮纹病菌、番茄早疫病菌、玉米小斑病菌、西瓜炭疽病菌以及水稻纹枯病菌等8种植物病原菌具有一定的抑制活性，其中化合物蒈酸基α-噻吩甲酰肼5f（R=α-thiophene）对苹果轮纹病菌的抑制率达85.0%，优于阳性对照百菌清。在用药量为100 μg·mL^-1时，化合物蒈酸基3′,4′-二甲氧基苯甲酰肼5j(R=3′,4′-OMe-Ph)、蒈酸基-m-甲氧基苯甲酰肼5d(R=m-OMe-Ph)、蒈酸基-m-甲基苯甲酰肼5b(R=m-Me-Ph)和蒈酸基苯甲酰肼5a(R=Ph)对油菜胚根生长的抑制率分别为88.5%、 86.1%、 85.1%和82.6%（均为A级活性水平），优于阳性对照丙炔氟草胺。     

利用H2与金属氧化物的选择性反应从CO中除H2

研究了一些氧化物的H2－TPR及CO－TPR行为,结果发现,Co3O4／Al2O3,NiO／SiO2,NiO和Pd／NiO的H2－TPR温度要低于它们的CO－TPR温度,特别是Pd／NiO样品,它的H2－TPR温度为598K,而其CO－TPR温度高达949K,差别为351K,因此有可能利用Pd／NiO在一定温度下选择性地与CO中的H2反应而将其除去. 实验结果表明,Pd／NiO可在603K及4000h-1的条件下从H2（0.34％）,CO（50％）和N2（余）的混合气中选择性地除去90％以上的H2,吸氢容量为每克样品55mL标准态H2.     

离子液体介导CO2化学转化研究进展

The efficient utilization of carbon dioxide (CO₂) as a C1 feedstock is of great significance for green and sustainable development. Therefore, the efficient chemical conversion of CO₂ into value-added products has recently attracted a lot of research attention in recent years. The transformation of CO₂ generally requires high-energy substrates, specific catalysts, and harsh reaction conditions due to its high thermodynamic stability and kinetic inertness. Consequently, several efforts have been dedicated toward the development of high-performance catalysts and new reaction routes for CO₂ conversion over the last few decades. To date, many routes of convert CO₂ into value-added chemicals have been proposed, together with the development of heterogeneous and homogeneous catalysts. Among the advanced catalysts reported to date, ionic liquids (ILs) have been widely investigated and show great potential for the efficient, selective, and economical conversion of CO₂ into highly valuable products under mild conditions, even under ambient conditions. Some task-specific ILs have been designed with unique functional groups (e.g., —OH, —SO₃H, —NH₂, —COOH, and —C≡N), which can act as the solvent, absorbent, activating agent, catalyst, or cocatalyst to realize the transformation of CO₂ under metal-free and mild conditions. In addition, a variety of catalytic systems composed of ILs and metal catalysts have also been reported for the transformation of CO₂, in which the combination of the IL and metal catalyst is responsible for CO₂ conversion with high efficiency. In this review article, we summarize the recent advances in IL-mediated CO₂ transformation into chemicals prepared via C—O, C—N, C—S, C—H, and C—C bond forming processes. ILs that can chemically capture CO₂ with high capacity are first introduced, which can activate CO₂ via the formation of IL-based carbonates or carbamates, thus realizing the transformation of CO₂ under metal-free and mild conditions. Recent progress in IL-mediated CO₂ transformations to form carbonates and various kinds of N- and S-containing compounds (e.g., oxazolidinones, ureas, benzimidazolones, formamides, methylamines, benzothiazoles, and other chemicals) as well as CO₂ hydrogenation to give formic acid, methane, acetic acid, low-carbon alcohols, and hydrocarbons has been summarized in this review with a focus on the reaction routes, catalytic systems, and reaction mechanism. In these reactions, ILs can simultaneously activate the substrate via strong H-bonding in addition to activating CO₂, and the cooperative effects among the ionic and molecular species and metal catalysts accomplish the reactions of CO₂ with various kinds of substrates to afford a wide range of value-added chemicals. Finally, the shortcomings and perspectives of ILs are discussed. In short, IL-mediated CO₂ transformations provide green and effective routes for the synthesis of high-value chemicals, which may have great potential for a wide range of applications.     

Synthesis of 1-Bromo-3-methoxy-4-propoxy-5-iodobenzene——A Novel Efficient Process for the Synthesis of Brominated Aromatic Compound

The reaction of aromatic carboxylic acid with oxalyl chloride gives rise to the corresponding acid chloride which without purification is treated with the sodium salt of mercaptopyridine oxide in the presence of 2,2-azo-bisisobutyronitrile (AIBN), radical initiator to give a brominated aromatic compound. After etherification and oxidation, 5-iodovaniline was converted to trisubstituted benzene carboxylic acid which give 1-bromo-3-methoxy-4-propoxy-5-iodobenzene by this new brominating process with a yield of 74%.     

稀土掺杂对锂离子电池正极材料LiMn2O4结构及电性能的影响

利用微波加热技术合成稀土掺杂基锂离子电池正极材料LiMn2-xRExO4(RE=Y，Nd，Gd，Ce)，通过XRD、循环伏安及恒电漉充放电测试研究了稀土掺杂离子对合成正极材料结构及电化学性能的影响。XRD测试结果表明，合适的掺杂量可以起到扩展锂离子脱嵌通道和稳定骨架结构的作用，稀土离子的引入可以部分取代原有的三价锰离子，由于稀土离子的离子半径较三价锰离子大，因此稀土掺杂锰酸锂材料的晶胞参数比未掺杂材料大，在一定程度上扩充了锂离子迁移的三维通道，更有利于锂离子的嵌入与脱嵌；循环伏安及恒电漉充放电测试结果表明稀土掺杂有效提高了LiMn2O4材料的电化学循环可逆性及循环稳定性。     

亚烷基卡宾与甲醛环加成反应机理的理论研究

用二阶微扰理论研究了单重态亚烷基卡宾与甲醛发生的三种环加成反应的机理 ，采用MP2/6－31G~*方法计算了势能面上各驻点的构型参数、振动频率和能量。根 据能量数据可以预言环加成反应（1）的a途径将是单重态亚烷基卡宾与甲醛环加成 反应的主要反应通道，该反应由两步组成：（I）亚烷基卡宾与甲醛生成了一富能 中间体（INT1a），是一无势垒的放热反应，（II）中间体异构化为产物亚烷基环 乙烷，其势垒为24.1 kJ·mol~(-1)(MP2/6-31G~*)。     

H_2O的表面增强Raman散射效应——在高浓度的ClO_4~-体系

采用可有效破坏H_2O分子间氢键的高浓度的ClO_4~-为主要支持电解质,在比通常低数十倍浓度的卤素离子体系中可获得很强的H_2O的表面增强Raman散射(SERS)信号,并可在含SCN~-体系中观察到H_2O的SERS现象。在0.1mol/LLiCl和3mol/L LiClO_4体系中的SERS谱表明电极表面上存在两种性质十分不同的H_2O分子,文中较详细地讨论这一异常现象。采用合适的电解质和电极表面处理可扩展对H_2O的SERS研究,更深入认识电化学界面的复杂结构。