TS分子筛催化性能研究Ⅰ．TS－2分子筛催化1，2－丙二醇液相氧化反应的研究

ＴＳ分子筛催化性能研究Ⅰ．ＴＳ－２分子筛催化１，２－丙二醇液相氧化反应的研究①伏再辉尹笃林（湖南师范大学精细催化合成研究所，长沙４１００８１）关键词ＴＳ－２分子筛１，２－丙二醇氧化催化氧化自１９８３年Ｔａｒａｍａｓｓｏ［１］首次合成具有ＺＳＭ－５结构...     

基于第一性原理方法研究ReOx在ReOx-Rh/ZrO2和ReOx-Ir/ZrO2催化的甘油氢解反应中的作用机制

采用密度泛函理论研究了ZrO₂负载的Ru基、Rh基以及Re改性的Rh基、Ir基催化剂上甘油氢解生成1,2-丙二醇和1,3-丙二醇的热力学过程, 重点考察了ReO_x调变催化剂活性和选择性的作用机制. 结果表明, Ru/ZrO₂和Rh/ZrO₂催化剂上甘油分解经由脱水-加氢反应途径, 1,2-丙二醇的生成是热力学有利过程, 其中Ru基催化剂活性更高. 在Re修饰的Rh基和Ir基催化剂上, 反应遵循直接氢解机理, 其中金属表面解离的氢原子进攻ReO_x团簇上与醇盐紧邻的C-O键是催化甘油转化为丙二醇最核心的步骤. ReO_x-Rh/ZrO₂催化剂上1,2-丙二醇为主要产物, 并伴随1,3-丙二醇的生成, ReO_x的修饰则显著提高了Ir/ZrO₂催化剂上1,3-丙二醇选择性. 与单金属催化剂上发生的间接氢解机理相比, 修饰催化剂上1,3-丙二醇选择性的提高可主要归因于Rh(Ir)-Re协同催化的直接氢解反应过程, 其中羟基化铼官能团有利于末端醇盐中间体的生成. ReO_x-Ir/ZrO₂催化剂上较大的Ir-Re团簇使得末端金属醇盐的立体优选性比次级醇盐更为突出, 从而具有最高的1,3-丙二醇选择性.     

Urchin-like CoCu Bimetallic Nanocomposites for Catalytic Hydrogenolysis of Glycerol to Propanediols

Bimetallic CoCu nanocomposites were synthesized in polyol by using Ru as heterogeneous nucleation agent and stearic acid as surfactant, and their catalytic properties were investi- gated by hydrogenolysis of glycerol to propanediols. It was found that the surfactant could induce Co nanocrystals to form nanowires as structure-directing agent, while it's ineffective for Cu because only spherical Cu particles were produced under the same condition. When Co²⁺ and Cu²⁺ coexist in polyol, Cu²⁺ is firstly reduced and forms the spherical particles, and then the Cu particles afford surface for the subsequential reduction of Co²⁺ and growth of Co nanocrystals to form the nanorods, obtaining the urchin-like CoCu nanocomposites. The catalytic performance in selective hydrogenolysis of glycerol to propanediols proposed that the CoCu urchin-like nanocomposites was superior to the Co nanowires possibly due to that the synergistic effect between Co and Cu component promoted conversion of glyc-erol and obtained the higher propanediol yields based on the specific surface areas of the catalysts.     

生物转化生产1,3-丙二醇的研究进展

综述了近几年生物转化生产1,3－丙二醇的研究进展,介绍了1,3－丙二醇工业生产的现状、生物转化的菌种及其生产能力、生物转化1,3－丙二醇的代谢途径、甘油的同底物发酵及基因工程对菌种的改造,展望了今后研究的发展方向。     

由M0.02Cu0.4Mg5.6Al1.98(OH)16CO3 (M=Ru,Re)水滑石为前驱体制备的双金属固体碱催化甘油氢解

采用共沉淀法合成了M_0.02Cu_0.4Mg_5.6Al_1.98(OH)₁₆CO₃ (M = Ru,Re)水滑石前驱体,然后经焙烧和还原制备了铜分散度较高的双功能M-Cu/固体碱催化剂.这些双功能催化剂在粗甘油氢解制备丙二醇反应中表现出了很好的催化活性.表征结果证明,M的加入增强了催化剂表面氢的吸附和活化,进而促进了甘油的转化.     

傅里叶红外光谱法直接测定丙二醇含量

研究了傅里叶变换红外光谱（FTIR）直接测定丙二醇水溶液中丙二醇含量的方法。结果表明，样品无须做前处理，丙二醇的含量与其红外吸收峰强度在实验浓度范围内皆有良好的线性关系，回收率为100.0%-101.4%，相对标准偏差为0.146%，该方法简单、快速，测定结果令人满意。     

A Magnetically Separable Catalyst for Synthesis of 1‐Phenoxy‐2‐propanol Via Atom‐economic Reaction

A magnetically separable catalyst Al₂O₃‐MgO/Fe₃O₄ was prepared by Al₂O₃‐MgO supported on magnetic oxide Fe₃O₄ and charactered by FT‐IR, XRD and SEM. The mixed oxides afforded high catalytic activity and selectivity for synthesis of 1‐phenoxy‐2‐propanol from phenol and propylene oxide with 80.3% conversion and 88.1% selectivity to 1‐phenoxy‐2‐propanol. Especially, facile separation of the catalyst by a magnet was obtained and the catalytic performance of the recovered catalyst was unaffected even at the forth run.     

八面沸石在精细有机合成中催化作用的研究 ⅩⅥ.脱铝超稳Y沸石催化苯甲醛与1,2-丙二醇的缩醛化反应

八面沸石在精细有机合成中催化作用的研究＊．脱铝超稳Ｙ沸石催化苯甲醛与１，２┐丙二醇的缩醛化反应袁先友张敏尹笃林＊＊伏再辉李谦和（湖南师范大学精细催化合成研究所，长沙４１００８１）关键词八面沸石，催化，苯甲醛，丙二醇，缩醛化反应缩醛（酮）类香料具有比其...     

Microwave spectrum of 1,2-propanediol

The microwave spectrum of the sugar alcohol 1,2-propanediol (CH₃CHOHCH₂OH) has been measured over the frequency range 6.5–25.0 GHz with several pulsed-beam Fourier-transform microwave spectrometers. Seven conformers of 1,2-propanediol have been assigned and ab initio electronic structure calculations of the 10 lowest energy forms have been calculated. Stark effect measurements were carried out on several of the lowest energy conformers to provide accurate determinations of the dipole moment components and assist in conformer assignment.     

甘油催化氢解制备精细化学品的研究进展

随着生物柴油产业的快速发展,作为副产物的甘油大量过剩,因而有效利用甘油既能促进生物柴油产业的良性发展,又能节约大量石油资源。通过甘油催化氢解的方式来制备高附加值化学品丙二醇、乙二醇和丙醇等是甘油转化研究中最有潜在应用价值的路径之一,甘油氢解反应易于实现连续化生产,且目标产物附加值高、选择性高,因而具有良好的经济效益。本文首先简要介绍了甘油化学,深入探讨了甘油的氢解机理,然后重点综述了甘油氢解制备1, 2-丙二醇、1, 3-丙二醇、乙二醇和丙醇高效催化剂的研究进展,并对甘油氢解未来的研究方向和发展趋势作了进一步展望。