草甘膦锆:干燥方法对微形貌的影响及甲醛吸附行为

本文运用扫描电子显微镜、X射线粉末衍射仪等手段对在不同干燥方法下得到的层状材料草甘膦锆分子聚集体的形貌及其对甲醛吸附性能进行了深入研究,探讨了干燥条件对材料形态的影响以及化合物形态对甲醛吸附不同的内在因素。研究结果表明:干燥方法不同,所得草甘膦锆的形貌有明显差别,应用超临界干燥技术得到的产物是具有大比表面(445m2·g-1)和大比孔容(5.32cm3·g-1)的三维网状结构,应用冷冻干燥技术得到的产物具有介孔结构,而使用喷雾干燥技术得到的产物为微孔与介孔共存微球。在对4种不同干燥产物对甲醛吸附性能的研究发现,甲醛分子在不同形态载体上的吸附能力差距很大,超临界干燥得到的草甘膦锆对甲醛吸附最大百分率(被吸附甲醛的质量占吸附组装体的百分含量)达到7.8%,且甲醛被吸附后热稳定性较好,具有较好的应用前景。     

氧化硅柱撑磺化磷酸-苯膦酸锆的合成及性能

以磷酸-苯膦酸锆为层板,合成并表征了硅柱撑的层柱磷酸-苯膦酸锆,并磺化了其中的苯环.磺化后的产物具有较高的酸量,在酯化反应中催化活性与硫酸相当.     

Zr-SBA-15介孔微球的制备、表征及其甲醇脱水性能研究(英文)

在SBA-15的合成体系中直接引入锆原子硝酸盐,用氨水调节体系的pH值到4.0~5.0,通过水热晶化处理后得到一系列不同含量的Zr-SBA-15介孔微球。利用XRD、氮吸附、SEM、TEM-EDS、ICP、FT-IR、和漫反射UV-vis等技术对该材料的组成、结构及形貌进行了表征。结果表明,这种杂化材料具有纳米介孔结构、高比表面积和空心微球等特征,空心微球形貌的形成可能与金属杂原子的引入、溶液pH值的调节有关,锆原子被高效率地引入到纳米介孔结构中,表面酸性与未改性前相比有了显著的提高,随着锆含量的增加,样品结构和表面酸性的变化直接影响着催化剂在甲醇脱水反应中的表现。     

自组装和共缩聚法制备磺酸基修饰的硅柱磷酸锆

以十六胺插层磷酸锆为原料,利用十二烷基二甲基苄基氯化铵为导向模板剂,通过正硅酸乙酯和巯丙基三甲氧基硅烷的层间共水解缩聚,并结合双氧水对巯丙基的熏蒸氧化,制备了磺酸基修饰的硅柱磷酸锆材料。通过XRD、SEM、N2吸附-脱附和FT-IR等方法对柱撑材料进行了结构表征。结果表明,通过调变预撑剂和模板剂中的碳链长度可以优化材料的柱撑结构和孔结构,磺酸基修饰的材料孔径分布在2.17 nm左右,比表面积可达163 m2·g-1,且保留有规整有序的柱撑磷酸锆层板结构。磺酸基的修饰则成功调变了材料的酸位性质,Br觟nsted酸量最高可达2.71 mmol·g-1,总酸量可达5.20 mmol·g-1。利用柠檬酸与正丁醇的酯化反应为探针反应,由于磺酸基修饰的硅柱磷酸锆材料具有独特的空间反应效应和较为丰富的Br觟nsted酸位,酯化反应转化率最高可达95.74%。     

阳离子表面活性剂-阴离子聚合物为模板剂合成硅基介孔材料

以阳离子表面活性剂十六烷基三甲基溴化铵和阴离子水溶性聚丙烯酸钠 (NaPAA) 混合物为模板剂, 在较高温度和碱度下采用 St?ber 法合成介孔材料. 通过调变助剂乙醇含量、晶化温度、晶化时间、NaPAA 含量和分子量等制得结构和形貌不同的硅基介孔材料. 研究表明, 这是 NaPAA 和乙醇共同作用的结果.     

烟草模板制备掺杂过渡金属铈锆固溶体及其催化氧化CO性能研究

以烟梗丝、烟叶片和烟梗条等材料为模板掺杂过渡金属合成了一系列铈锆固溶体材料.对合成的材料进行了扫描电子显微镜(SEM)、N2吸附-脱附、程序升温还原(H2-TPR)、X-射线衍射法(XRD)、储氧量(OSC)、X-射线光电子能谱(XPS)等表征.对铈锆固溶体材料进行CO氧化活性评价,结果表明不同烟草模板制备的铈锆固溶体性能不同.以烟叶片为模板制备的掺铜铈锆固溶体具有极高的储氧量,高达2961μmol/g,但该材料催化氧化CO的活性并非最强.以烟梗丝为模板制备的掺铜铈锆固溶体在铈锆比为45∶45∶10时,对CO氧化有着很好的催化活性,起燃活性温度(T50)为91℃.     

硅铝柱撑磷酸锆的合成及在大豆油甲酯环氧化反应中的催化性能

基于模板剂导向组装的方法制备了硅铝柱撑磷酸锆.对材料结构进行了表征,分析了硅铝柱撑结构的形成机制.结果表明,材料中铝分别以四面体与八面体的形式嵌入在柱撑结构的内部和层板表面.通过大豆油甲酯的环氧化反应考察了所得硅铝柱撑磷酸锆的催化性能,其催化选择性可达91.7%.反应历程的分析结果表明良好的层板柱撑结构使大分子的反应物能与层间活性位充分接触.硅铝柱撑磷酸锆的酸位特点及催化反应的动力学分析表明,铝源的引入提高了柱撑材料的Lewis酸含量,改善了柱撑磷酸锆对大豆油甲酯环氧化的催化性能.     

一种二维多孔窗口型膦酸锆材料的合成及其对不同金属离子的吸附性能

合成了一种二维窗口型膦酸锆材料β-丙氨酸-N,N-双亚甲基膦酸锆(ZrNCP),采用X射线衍射仪、扫描电镜、透射电镜分析了合成产物的相组成和微观结构;利用N2吸脱附试验装置测定了合成产物对不同金属离子的吸附性能,考察了浓度、温度及pH对其吸附性能的影响.结果表明,合成产物内部存在大量分布均匀的微介孔,材料微观形貌为规整片状.随着金属离子半径的增大,ZrNCP对各种金属离子的平衡吸附量(mmol/g)呈逐渐减小趋势.     

大孔MgO/ZrO2固体碱的制备及催化性能

以多孔聚合物为整体型模板,利用锆酸四丁酯原位水解并结合高温烧结的方法制备出大孔ZrO2载体,通过Mg(NO3)2溶液浸渍、高温煅烧制备出大孔MgO/ZrO2复合材料。SEM、FTIR、XRD、TG-DSC表征发现ZrO2载体是由三维连续的纳米薄层构成的大孔材料,MgO以纳米颗粒形式沉积在ZrO2的三维超薄层上。进一步通过CO2-TPD手段发现该ZrO2表面具有弱碱性位,MgO的负载显著增加了复合物的碱性。以碳酸二甲酯和异辛醇酯交换合成碳酸二异辛酯为探针反应,考察焙烧温度及活性组分负载量等制备条件对大孔MgO/ZrO2固体碱催化活性的影响。结果表明,该催化剂对碳酸二异辛酯的合成具有较好的催化活性,当焙烧温度为600℃,MgO含量为50%时目标产物的产率可高达到65%。     

超临界甲烷在氯化锆层柱纳米材料中吸附的分子模拟

用巨正则MonteCarlo(GCMC)方法模拟了甲烷在氯化锆层柱材料中的吸附。模拟中,氯化锆层柱材料模型化为柱子均匀分布在层板间的层柱孔,非极性分子甲烷采用Lennard-Jones分子模型,层板墙采用Steele的10-4-3模型,流体分子与柱子的相互作用采用点-点(sitetosite)的方法计算。在高度理想化模型的基础上,引入交互作用参数kfw,建立了有效势能模型。通过实验数据确定交互作用参数kfw,从而使该模型能有效地表征流体与层板墙的相互作用。根据77K温度下氮气的实验吸附数据,确定了流体和层板墙间的交互相作用参数。然后用这个有效的参数kfw=0.65模拟了三个超临界温度下氯化锆层柱材料中甲烷的吸附情形,得到了它位的吸附等温线,局部密度分布以有流体分子在层柱微孔中的瞬时构象,并分析了温度对材料吸附性能的影响。结果表明GCMC方法是预测材料吸附性能的一种强有力的工具。     

银纳米颗粒负载阶层多孔二氧化硅块体的制备及表征

以溶胶-凝胶伴随相分离法制备的阶层多孔二氧化硅作为载体,3-氨丙基三乙氧基硅烷（APTES）为改性剂,乙醇为还原剂,在阶层多孔二氧化硅固体骨架上进行银纳米颗粒均匀负载. 利用扫描电镜（SEM）、透射电镜（TEM）、X射线衍射（XRD）、汞压、N₂吸附/脱附、X射线光电子能谱（XPS）等测试技术对银纳米颗粒负载阶层多孔二氧化硅进行了表征,探讨了APTES表面改性、乙醇还原机理以及银纳米颗粒负载块体的孔结构特征变化规律. 结果表明：APTES表面改性将氨基接枝于阶层骨架上,氨基与银离子形成银氨离子,银氨离子经乙醇还原后将平均粒径约16 nm的银纳米颗粒成功负载于二氧化硅的大孔及介孔内部;负载后的阶层多孔块体的大孔骨架未受到破坏,但其比表面积由418 m²·g^-1下降到254 m²·g^-1,两次还原负载能提高银纳米颗粒的负载量.     

Effect of Porogen Solubility Parameter on Structure of Chromatographic Supports with Large Pores

The macroporous microspheres were prepared through suspension polymerization based on a copolymer of glycidyl methacrylate and ethylene glycol dimethacrylate. The effect of porogen on the microspheres structure was evaluated in terms of pore size and surface area. Porogen contained dichloromethane (δ = 9.7 (cal cm^–3)^1/2) and N-octanol (δ = 10.3 (cal cm^–3)^1/2) which were correspond to a good and poor solvent, respectively. The solubility parameter of porogen was controlled in the range of 9.89–10.09 (cal cm^–3)^1/2. The pore size of microspheres increased with the increase of difference value of solubility parameter between the polymer and the porogen. On the contrary, the surface area of microspheres decreased. The anion exchange media was prepared through coupling poly(ethylene imine) in the microspheres and the proteins transport was determined by frontal analysis method. The macroporous microspheres with 257 nm pore size could still afford a high proteins capacity (45.1 mg mL^–1). These macroporous supports showed great potential in rapid separation of proteins.     

Molecularly imprinted polymeric shell coated monodisperse‐porous silica microspheres as a stationary phase for microfluidic boronate affinity chromatography

Molecular imprinting of cis‐diol functionalized agents via boronate affinity interaction has been usually performed using nanoparticles as a support which cannot be utilized as a stationary phase in continuous microcolumn applications. In this study, monodisperse‐porous, spherical silica particles in the micron‐size range, with bimodal pore diameter distribution were selected as a new support for the synthesis of a molecularly imprinted boronate affinity sorbent, using a cis‐diol functionalized agent as the template. A specific surface area of 158 m²/g was achieved with the imprinted sorbent by using monodisperse‐porous silica microspheres containing both mesoporous and macroporous compartments as the support. High porosity originating from the macroporous compartment and sufficiently high particle size provided good column permeability to the imprinted sorbent in microcolumn applications. The mesoporous compartment provided a large surface area for the parking of imprinted molecules while the macroporous compartment facilitated the intraparticular diffusion of imprinted target within the microsphere interior. A microfluidic boronate affinity system was first constructed by using molecularly imprinted polymeric shell coated monodisperse‐porous silica microspheres as a stationary phase. The synthetic route for the imprinting process, the reversible adsorption/ desorption behavior of selected target and the selectivity of imprinted sorbent in both batch and microfluidic boronate affinity chromatography systems are reported.     

铁掺杂的高比表面二氧化硅的制备及其苯酚降解性能

研究了以聚乙二醇为模板剂、正硅酸乙酯(TEOS)为硅源制备铁掺杂的多孔二氧化硅的方法。开发了一步完成多孔材料制备和掺杂的新工艺。研究了不同的铁元素掺杂量对样品性能的影响。采用低温氮吸附、SEM、FTIR、XRD方法表征了样品的比表面、孔结构和表面基团等信息。最优样品比表面大于700 m²·g^-1、孔容大于1 mL·g^-1。研究了所制备的多孔材料和双氧水共同降解水中苯酚的能力,研究发现负载铁的催化剂可以在很宽的pH值范围内(3~8)和双氧水协同使用,这可能是因为铁元素被牢固负载于多孔二氧化硅的骨架上,避免了其在高pH值下发生的水解反应。     

A Smart Glycol‐Directed Nanodevice from Rationally Designed Macroporous Materials

We have developed a smart nanodevice for the highly efficient and selective detection of glycoproteins. This polyfunctional device is fabricated through the rational functionalization of macroporous silica foam (MOSF) materials with a boron species (B‐MOSF) and amino groups (NH₂‐MOSF), and then the integration of MOSF, B‐MOSF and NH₂‐MOSF materials. In such a device, a macroporous structure with very large‐pore sizes (diameters≈100 nm) and high‐pore volumes (>0.65 cm³ g^?1) is advantageous to efficiently fasten the enzymatic reaction. The targeted specific glycopeptides of the products can be selectively isolated and enriched in B‐MOSF through the chemo‐affinity between boronic acid and glycol groups, while the non‐specific peptides are released to the solutions, or further purified by MOSF and NH₂‐MOSF, which have opposite charges. As a result, the protein digestion and glycol‐peptide isolation can be simultaneously achieved in the functionalized macroporous materials in one step, which is a great advantage compared to conventional multi‐procedure and time‐consuming techniques.     

Template‐Synthesized Porous Silicon Carbide as an Effective Host for Zeolite Catalysts

A facile method has been developed for the fabrication of porous silicon carbide (SiC) by means of sintering a mixture of SiC powder and carbon pellets at a relatively lower temperature, that is, 1450 °C, in air. The pore density and the total pore volume of the resulting porous SiC could be tuned by changing the initial SiC/C weight ratio. The structure evolution and the associated property changes during the preparation were examined through X‐ray diffraction, scanning electron microscopy, thermogravimetric analysis, ²⁹Si magic‐angle spinning (MAS) NMR spectroscopy, and mercury‐intrusion porosimetry analyses. Silica and SiO_xC_y ceramics formed in situ during the calcination process acted as binders of the porous SiC grains. The porous SiC can be used as a host for the growth of ZSM‐5 zeolite crystals to form the ZSM‐5/porous‐SiC composite material. After loading another catalytic active component of molybdenum, a novel catalytic material, Mo‐ZSM‐5/porous‐SiC, was obtained, which exhibited improved catalytic activity in the methane dehydroaromatization reaction.     

Synthesis of macroporous polymer rods based on an acrylamide derivative monomer

New macroporous polymer rods were prepared by free‐radical crosslinking copolymerization from N‐acryloyl‐tris(hydroxymethyl)aminomethane and N,N′‐methylenebisacrylamide as a crosslinking agent with different porogenic mixtures and with azobisisobutyronitrile as an initiator. The porous properties of these materials were controlled through changes in the proportions of the porogenic mixture, the polymerization temperature, or the concentration of the crosslinking agent. Pore size distribution profiles that shifted toward a larger pore size were obtained in the following cases: when the percentage of the coporogen was increased, when the copolymerization reactions were carried out at a low temperature (55 °C), and when the crosslinking concentration was reduced. Alternatively, a porogenic mixture formed from dimethyl sulfoxide and a 1:1 combination of tetradecanol and poly(ethylene glycol) 6000 as coporogens yielded a polymer rod with a high porosity and pore size. These hydrophilic materials are promising as base supports for different chromatographic processes and as throughput bioreactors. © 2006 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 44: 6616–6623, 2006     

疏水介孔二氧化硅膜的制备与表征

用甲基三乙氧基硅烷(MTES)代替部分正硅酸乙酯(TEOS)作为前驱体，以聚乙烯醚-聚丙烯醚-聚乙烯醚三嵌段共聚物(P123)作有机模板剂，通过共水解缩聚反应制备了甲基修饰的介孔SiO₂膜。利用N₂吸附、FTIR、²⁹Si MAS NMR以及接触角测量仪对膜的孔结构和疏水性进行了表征。结果表明，修饰后的膜材料具有良好的介孔结构，最可几孔径为4.65 nm，孔体积为0.69 cm³·g^-1，比表面积为938.4 m²·g^-1；同时疏水性明显提高，当n_MTES/n_TEOS达到1.0时，其对水的接触角达到109°± 1.1°。气体渗透实验表明气体通过膜孔的扩散由努森机制所控制。     

Pore structural studies of monodisperse porous polymer particles

Monodisperse polystyrene latex particles with molecular weight on the order of 10⁶ were used as inert diluents for the preparation of monodisperse porous styrene-divinylbenzene copolymer particles via seeded emulsion polymerization techniques. Mercury porosimetry and nitrogen adsorption-desorption isotherms were used to assess pore structure and pore size distribution. Pore size distribution was very sensitive to the molecular weight of the polystyrene latex particles used as inert diluent. Qualitative evidence from the techniques used indicated that the monodisperse porous polymer particles were macroporous (average pore diameter > 500 Å) in nature. As the molecular weight of the linear polymer decreased, the porous structure of the polymer particles ranged in complexity across the spectrum of macro/mesopore structures. Scanning electron microscope results indicated the existence of voids between the microspheres and their agglomerates within the porous polymer particle, and nitrogen adsorption isotherms confirmed that the pores were due to interstices between these crosslinked microspheres and agglomerates.