介孔分子筛增强聚双环戊二烯

分别采用介孔分子筛SBA-15原位聚合及SBA-15负载催化剂原位聚合的方法,制备聚双环戊二烯(PDCPD)/SBA-15复合材料.比较不同制备方法对PDCPD/SBA-15力学性能的影响,运用XRD、TEM、TG、SEM等研究了SBA-15的增强机理.研究结果表明,采用原位聚合的方法制备的复合材料,SBA-15孔道中...     

SMA/蒙脱石纳米复合材料增容PA6/ABS共混体系

采用原位插层法制备苯乙烯-马来酸酐交替共聚物/蒙脱石(SMA/MMT)纳米复合材料增容PA6/ABS共混体系,并与SMA及MMT的增容效果进行比较,运用TEM、SEM、DSC及XRD研究了增容剂SMA/MMT及MMT的增容机理.结果表明,采用SMA做增容剂,体系机械性能下降;MMT可使体系拉伸强度提高,但冲击强度下降;采用SMA/MMT纳米复合材料做为增容剂,可提高共混体系的强度及韧性.TEM、XRD、DSC及SEM研究结果表明,PA6/ABS/(SMA-MMT)体系中MMT主要分布于两相界面处,ABS及PA6分子链可进入MMT层间,形成类似于共聚物结构,起到增容剂的作用,从而降低分散相粒径,增加两相界面作用力,有利于体系力学性能的提高.PA6/ABS/MMT体系中MMT主要分布于连续相PA6中,虽然对分散相粒径影响较小,但增强了PA6相强度,使得体系力学性能提高.     

层状硅酸盐固定化肌红蛋白在有机溶剂中的催化活性和稳定性

在温和条件(室温及pH=7)下,通过剥离重组实现了肌红蛋白分子在层状硅酸盐magadiite纳米粒子层间的固定化,系统考察了固定化后肌红蛋白在不同疏水度的有机溶剂中催化邻苯二胺氧化反应的性能.结果表明,固定化肌红蛋白在中等疏水度的有机溶剂中呈现出比自由肌红蛋白更高的催化活性和稳定性.结合固定化肌红蛋白在有机溶剂中的动力学研究结果,初步探讨了其具有高催化活性的原因.     

Electrical properties of conductive polymer composites prepared by an innovational method

<正>An innovational method that poly(styrene-co-maleic anhydride)(SMA),a compatibilizer of immiscible nylon6/polystyrene(PA6/PS) blends,was first reacted with carbon black(CB) and then blended with PA6/PS,has been employed to prepare the PA6/PS/(SMA-CB) composites of which CB localized at the interface.In PA6/PS/CB blends,CB was found to preferentially localize in the PA6 phase.However,in the PA6/PS/(SMA-CB) blends,it was found that CB particles can be induced by SMA to localize at the interface.The electrical porperties of PA6/PS/(SMA-CB) composites were investigated.The results showed that the composites exhibited distinct triple percolation behavior,i.e.the percolation is governed by the percolation of CB in SMA phase,the continuity of SMA-CB at the interface and the continuity of PA6/PS interface.The percolation threshold of PA6/PS/(SMA-CB) was only 0.15 wt%,which is much lower than that of PA6/PS/CB.Moreover,the PTC(positive temperature coefficient) intensity of PA6/PS/(SMA-CB) composites was stronger than that of PA6/PS/CB and the negative temperature coefficient(NTC) effect was eliminated.The electrical properties of PA6/PS/(SMA-CB) were explained in terms of its special interface morphology:SMA and CB localize at interphase to form the conductive pathways.