微纳尺度无机-有机杂化凝胶固定化木瓜蛋白酶研究

以吸附-絮凝耦合方法制备了微纳尺度的纳米TiO2-聚丙烯酰胺(polyacrylamide,PAM)杂化凝胶固定化酶.利用扫描电镜(SEM)、能谱面扫描(EDS)、粒度分析表征了杂化凝胶絮凝酶形貌、尺寸及分散性.通过对酸碱度有效调控,以及表面Zeta电位分析,探寻了酶-纳米复合凝胶静电作用机制.结果表明,静电相互作用力对酶的负载和颗粒粒度分布影响较大,在pH=7.0,TiO2和木瓜蛋白酶(papain,PA)质量比为7.5∶1时,固定化酶负载量达121.84 mg/g,负载率91.38%;杂化凝胶固定化酶尺寸约为0.444μm左右,固定化酶在杂化凝胶载体上高度分散.该杂化凝胶絮凝酶经过5批次反应后相对酶活力能保持在50%以上.可见由吸附-絮凝法制备的微纳尺度的杂化凝胶固定化酶,分散性好,稳定性好,酶负载量高,这是一种利用纳米材料和微纳结构进行固定化酶的新途径.

有机-无机杂化凝胶法合成YAG∶Ce^(3+)荧光粉的包膜及其稳定性

本文以金属硝酸盐为原料,柠檬酸为配位剂的有机-无机杂化凝胶法来合成掺杂三价铈离子的钇铝石榴石荧光粉,采用X-射线衍射法研究了杂化凝胶在煅烧过程中的相转变机制。结果表明:杂化凝胶在煅烧过程中可以通过两条途径形成Y3Al5O12(YAG)相:一是由无定形Y2O3和Al2O3直接向YAG相的一步相转变;二是由无定型Y2O3和Al2O3经由YAlO3(YAP)和γ-Al2O3向YAG相的两阶段相转变,在900℃得到结晶性好的纯YAG∶Ce3+荧光粉,其最大激发波长为459nm,最大发射峰波长为550nm;在荧光粉表面包覆氧化铝和氧化镧,将使荧光粉的荧光强度稍有降低,但对荧光粉的稳定性有很好的改进作用。

APTES改性蒙脱土对镁合金表面杂化溶胶-凝胶涂层防护性能的影响

针对蒙脱土与有机-无机杂化溶胶-凝胶体系较差的相容性,使用APTES对蒙脱土进行接枝改性,通过在蒙脱土表面引入氨基建立与溶胶-凝胶体系间较强的键合,在镁合金表面制备更加致密、稳定的复合涂层。对蒙脱土的表征结果表明APTES成功接枝到了蒙脱土片层上。结果分析表明,相比于纯溶胶-凝胶涂层,添加AP-MMT的溶胶-凝胶涂层的耐蚀性具有一定程度的提高。进一步对涂层样品浸泡在0.05 mol/L NaCl溶液中不同时间的电化学阻抗谱(EIS)分析表明,掺杂前后的溶胶-凝胶涂层具有不同的失效机制,这些都与改性蒙脱土的添加使得涂层具有更加致密的结构有关。

Synthesis and characterization of hybrid organic-inorganic materials based on EA-MAn-APTES and silica

Poly (EA-MAn-APTES)/silica hybrid materials were successfully prepared fromEthyl acrylate (EA), maleic anhydride (MAn) and tetraethoxysilane (TEOS) in the presence of acoupling agent 3-aminopropyltriethoxysilane (APTES),by free-radical solution polymerization and insitu sol-gel process. The mass fraction of TEOS varied from 0 to 25%. The hybrid materials werecharacterized by the methods of FT-IR spectra, solvent extraction, scanning electron microscope (SEM), transmission electron microscope (TEM), differential scanning calorimetry (DSC) andthermogravimetric analysis (TGA) measuring apparatus to get their structures, gel contents,morphologies, particle sizes and thermal performances. The results show that the covalent bonds arebetween organic and inorganic phases, gel contents in the hybrid materials are much higher, theSiO_2 phase is well dispersed in the polymer matrix, silicon dioxide exist at nanoscale in thecomposites and have excellent thermal stability.