氧化钛催化羟基磷灰石分解制备可降解磷酸钙陶瓷

本文将纳米锐钛矿型氧化钛(TiO2)作为催化剂添加到羟基磷灰石(HA)中,经烧结制成可降解的磷酸钙陶瓷,采用X射线衍射(XRD),扫描电镜(SEM),体外模拟实验等手段对不同制作工艺的陶瓷进行表征,考察TiO2的添加量和保温时间对磷酸钙陶瓷性能的影响。实验表明,在较低的温度下,TiO2可以降低HA的高温稳定性,使HA分解成磷酸四钙(TTCP)和磷酸三钙(TCP)。由于TCP具有良好的降解性,TiO2的加入极大的提高了HA的降解速率,且随着TiO2添加量的增加降解速率逐渐增大,保温时间越长,降解速率愈小;浸泡SBF结果显示,TiO2的加入可以提高陶瓷沉积活性磷灰石层的能力,但沉积能力与TiO2添加比例不成正比,添加7wt%的材料沉积最快;细胞实验表明,TiO2的加入不影响HA促进细胞增殖分化的能力。使用氧化钛催化分解HA,可能是制备具有良好生物学性能的可降解磷酸钙陶瓷的有效手段。     

两种形貌的介孔SiO2对纤维素内切酶吸附性能的研究

以EDTA2-、SO42-作为反离子分别合成了具有管状和圆盘状结构的介孔SiO2,并测定了2种介孔SiO2焙烧至不同温度时的表面积、孔体积参数,及其等电点;通过752分光光度计在550nm处测定纤维素内切酶的吸光度,研究了2种形貌的介孔SiO2对纤维素内切酶的吸附性能,同时测定了固定酶的活性。结果表明,管状和圆盘状结构的介孔SiO2对纤维素内切酶的吸附等温线分别为Ⅱ和Ⅰ型;介孔SiO2焙烧至700℃时,两者皆为Ⅱ型;至850℃时,前者转化为Ⅰ型,而后者转化为Ⅴ型。吸附等温线类型与介孔SiO2的结构、等电点以及酶分子尺寸与介孔尺寸的相匹配有关。酶经过介孔SiO2吸附固定后,稳定性明显提高;其中,管状结构的介孔SiO2对酶具有最大的负载量,但固定酶的活性却较低。     

阳离子和两性混合表面活性剂为模板合成三维六方介孔二氧化硅

用阳离子表面活性剂CnTAB(n=12,14,16,18)和两性生物表面活性剂SDG以8∶2的摩尔比混合作为模板剂,在酸性条件下晶化,碱性条件下老化合成了三维有序介孔二氧化硅。合成的产物用XRD、SEM、TEM和N2吸附进行表征。结果表明,在不同链长的表面活性剂CnTAB(n=12,14,16,18)中,C14TAB与SDG混合所得样品C14DG的有序度最好。而C16TAB和C18TAB与SDG混合所得样品的孔径约为9 nm。两性表面活性剂SDG对产物的形貌和三维六方结构都有影响。     

TiO2‐assisted Photocatalytic Degradation of Vitamin B12 in Aqueous Solution:Influencing Factors,Kinetics, and Reaction Investigations

The photodegradation (λ=365 nm) of the biomolecule vitamin B₁₂, catalyzed by the photocatalyst TiO₂ nanoparticles (NPs), has been investigated in aqueous suspension. The photodegradation process of vitamin B₁₂ has been monitored by means of electronic absorption (Abs), Fourier‐transform infrared (FT‐IR), and resonance Raman (RR) spectroscopies, respectively. The results show that only under UV illumination in the presence of TiO₂ is there effective degradation, and the photocatalytic degradation of vitamin B₁₂ is strongly influenced by the amount of TiO₂ NPs, the pH, and the initial concentration of vitamin B₁₂. The photocatalytic reaction kinetics of vitamin B₁₂ conforms to a Langmuir‐Hinshelwood isotherm model. Changes involving the three structural units of the carbon‐metal bond C–Co, the organic corrin macrocycle combined with the benzimidazole nucleotide, and the inorganic CN in the vitamin B₁₂ molecule during the photocatalytic degradation are also discussed.     

Preparation of Helical Mesoporous Ethenylene-silica Nanofibers with Lamellar Mesopores on Their Surface

The morphologies and pore architectures of mesoporous ethenylene‐silica were controlled using cetyltrimethylammonium bromide (CTAB) as template and (S)‐β‐citronellol as a co‐structure‐directing agent under basic conditions. When the (S)‐β‐citronellol/CTAB molar ratios are in the range of 0.75–2.0, helical nanofibers were obtained. With increasing the (S)‐β‐citronellol/CTAB molar ratio, the lengths of the nanofibers increases. Lamellar mesopores were identified on the surfaces of the nanofibers prepared in the (S)‐β‐citronellol/CTAB molar ratio range of 1.5–2.0. At the (S)‐β‐citronellol/CTAB molar ratio of 2.5:1, nanoparticles with nanoflakes on the surfaces were obtained. The field emission scanning electron microscopy images taken after different reaction times indicated that the helical pitches of the nanofibers decreased with increasing the reaction time. Helical 1,4‐phenylene‐silica and methylene‐silica nanofibers were also prepared. The results indicated that the morphologies and pore architectures of the obtained organic‐inorganic hybrid silicas are also sensitive to the hybrid silica precursors. Helical ethenylene‐silica nanofibers with lamellar mesopores on their surfaces can be also prepared using the mixtures of CTAB and racemic citronellol within a narrower citronellol/CTAB molar ratio range.     

Effects of cosolvent on formation and morphology of microspheres in precipitation polymerization of divinylbenzene in supercritical carbon dioxide

Precipitation polymerizations of divinylbenzene(DVB) in pure supercritical carbon dioxide,and parallel runs with presence of a cosolvent were carried out.The results showed that use of acetone as the cosolvent contributed greatly to the formation of the monodisperse microspheres.PDVB microspheres,with obviously higher uniformity than reported up to date,were achieved using 6-7 mL of acetone in a reactor of 50 mL with DVB concentration of 0.4 mol/L under 16 MPa,a much lower pressure than previously reported without use of cosolvent.     

高热稳定性介孔氧化锆的合成及表征

利用阴离子表面活性剂作模板,通过水热均匀沉淀方法成功合成了具有高热稳定性的介孔氧化锆.该方法以十二烷基苯磺酸钠(SDBS)作为介孔结构的导向剂,其含S基团在煅烧时起到了稳定剂的作用.采用透射电镜、氮气吸附-脱附、X射线粉末衍射、红外光谱测试手段对样品进行了表征.研究表明,以SD-BS为模板剂合成的介孔氧化锆具有蠕虫状介...     

N-羟基邻苯二甲酰亚胺和二氧化锰高效催化对硝基甲苯氧化

采用N-羟基邻苯二甲酰亚胺(NHPI)和二氧化锰(MnO2)作为催化剂催化对硝基甲苯的氧化反应以制备对硝基苯甲酸;对反应条件进行了优化.结果表明,采用10%(与原料的摩尔比)NHPI和10%(与原料的摩尔比)MnO2作为催化剂,在110℃、氧气压力0.4 MPa下反应4 h,对硝基甲苯的转化率为97%,对硝基苯甲酸的分...     

介孔L材料CMK-3对甲基紫的吸附性能

合成了高度有序的具有二维六方(P6mm)结构的介孔碳材料CMK-3;利用X射线衍射分析了CMK-3的晶体结构,利用氮气吸脱附(BET)试验测定了孔体积;测定了CMK-3对水溶液中甲基紫的吸附行为,考察了不同pH、温度及浓度下水溶液中甲基紫的静态吸附行为,并分析了酸性、中性、碱性条件下吸附剂对甲基紫和罗丹明B混合溶液的竞...     

Self-assembled highly ordered ethane-bridged periodic mesoporous organosilica and its application in HPLC

Monodisperse spherical periodic mesoporous organosilicas (PMOs) with ethane integrated in the framework were synthesized and their application as stationary phase for chromatographic separation is demonstrated. The ethane-PMOs were prepared by condensation of 1,2-bis(triethoxysilyl)ethane (BTSE) in basic condition using octadecyltrimethylammonium chloride (C(18)TMACl) as template and ethanol as co-solvent. The morphology and mesoporous structure of ethane-PMOs were controlled under different concentrations of sodium hydroxide (NaOH) and EtOH. The results of scanning electron microscopy (SEM), transmission electron microscopy (TEM), powder X-ray diffraction (XRD), nitrogen sorption measurement, Fourier transform infrared spectroscopy (FT-IR) and elemental analysis showed that ethane-PMOs have spherical morphology, uniform particle distribution, highly ordered pore structure, high surface area and narrow pore-size distribution. The column packed with these materials exhibits good permeability, high chemical stability and good selectivity of mixtures of aromatic hydrocarbons in normal phase high-performance liquid chromatography (HPLC).