易剥离镍基二维金属-有机框架晶态材料的制备、结构及表征

二维金属-有机框架纳米片是一类新兴的二维材料,其与块体材料相比具有更多可暴露的活性位点、快速的质子或电子传递等优点。制备易剥离的二维金属-有机框架纳米片的前驱体,即二维金属‐有机框架晶态材料是当前的一大挑战。以廉价且毒性较小的乙醇为反应介质、均苯三甲酸和N-基咪唑为共同配体,通过简单的一锅法制备了结构新颖的镍基二维金属-有机框架晶态材料Ni(C_(9)H_(3)O_(6))(C_(4)H_(6)N_(2))_(2)·0.6(C_(2)H_(5)OH)(1)和Ni_(3)(C_(9)H_(3)O_(6))_(3)(C_(5)H_(8)N_(2))_(6)·3.25(C_(2)H_(5)OH)(2),并对其进行了相关表征和剥离。实验中采用的反应介质乙醇毒性小、价格低廉、对环境污染性小且可循环利用,符合绿色化学的发展要求。该制备方法可为设计合成易剥离二维金属‐有机框架晶态材料提供借鉴。

SIS热熔性可剥离材料性能研究

选用合适组成及分子量的苯乙烯-异戍二烯-苯乙烯(SIS)三嵌段共聚物作成膜物质,添加某些辅助料,研制了一种热熔性可剥离材料.探讨了添加料超细二氧化硅、活性碳酸钙、流平剂的用量对所制可剥离材料性能的影响.研究结果表明,超细二氧化硅、活性碳酸钙、流平剂的添加量分别占物质总质量的13.0%、10.0%、1.0%时,该材料膜的抗张强度达7.5MPa,断裂伸长率为410%,剥离强度13kN·m-1,涂膜邵尔硬度21,同时其膜具有良好的耐热性,是一种用于钢材、铝材、玻璃等基材保护的性能较为理想的热熔性可剥离材料.

乳液聚合法制备剥离型PS/MMT纳米复合材料

以阳离子表面活性剂十八烷基三甲基氯化铵(OTAC)和烯丙基十八烷基二甲基氯化铵(ATAC)为插层处理剂改性蒙脱土(MMT),原位乳液聚合分别制备了PS/C18MMT和PS/AC18MMT两种纳米复合材料.XRD和TEM分析表明,MMT均被剥离成单个或几个片层无规的分散在PS基体中,TGA分析表明,MMT的加入提高了材料的耐热性能,当PS基体与有机化处理的MMT片层发生一定的化学连接后,PS/AC18MMT纳米复合材料表现出更好的耐热性能.动态力学分析表明,MMT的加入提高了PS的玻璃态储能模量,降低了材料的动态损耗;PS/AC18MMT纳米复合材料的玻璃化温度较PS有所提高,而PS/C18MMT的玻璃化温度与PS相比略有降低.

用于混凝土表面放射性沾染清除的剥离型膜材料研究

制备了一种适用于混凝土表面放射性沾染清除的剥离型膜材料,单次去污率高达91.98%以上。采用常见成膜乳液中的水性纯丙乳液、水性醋丙乳液和水性橡胶乳液进行基础配方实验,得出三种乳液的最佳复配质量比为5∶3∶2,此时复配乳液对放射性铀尘的去污率为81.68%。在此配方的基础上,研究了表面活性剂十二烷基苯磺酸钠(SDBS)和络合剂EDTA-2Na的掺杂量对材料去污性能的影响规律。结果表明:表面活性剂SDBS能通过降低表面张力、增溶等作用提高材料的去污率,当SDBS的质量分数控制在5%时去污率最高达到87.25%,相比于基础配方单次去污率的增幅为6.8%;适量的EDTA-2Na能通过与核素形成金属螯合物来增加去污率,EDTA-2Na的质量分数控制在0.5%～1.0%时材料的去污率最优,达到91.98%～92.23%。

原位插层聚合制备PVC/蒙脱土纳米复合材料

采用氯乙烯单体直接插层到蒙脱土中进行原位插层聚合 ,制备纳米复合材料 ,并用小角X射线衍射 (XRD)、扫描电子显微镜 (SEM)和电子探针技术对复合材料进行了结构表征。实验结果表明 :采用原位插层聚合法制得的PVC/蒙脱土 (MMT)

PU/P(MMA-co-MAH)/OMMT纳米复合材料的制备与性能研究

将插层纳米复合技术与互穿网络共混技术相结合,通过同步插层聚合法制备PU/聚(甲基丙烯酸甲酯-马来酸酐)[P(MMA-co-MAH)]/有机蒙脱土(OMMT)纳米复合材料。试验结果表明,PU/P(MMA-co-MAH)/OMMT纳米复合材料为剥离/插层型纳米复合材料,各项物理性能较优;其优化制备条件是:过氧化苯甲酰、二甲基丙烯酸乙二酯、OMMT和MAH在单体中的质量分数分别为0.008,0.02,0.05和0.05;PU/PMMA共混比为60/40;亚甲基双邻氯苯胺因数为0.8。

2D materials via liquid exfoliation:a review on fabrication and applications

Since graphene was discovered, the study of two-dimensional(2D) materials with atomic thickness has become a hot spot. To prepare different 2D materials,different methods have been groped, such as mechanical exfoliation, chemical vapor deposition(CVD), liquid-phase exfoliation. This review mainly introduced the sonication liquid-phase exfoliation, an effective method to prepare 2D materials. Compared with mechanical exfoliation and CVD methods, liquid-phase exfoliation is convenient and costeffective and provides high yield. We focused on both theoretical and experimental details of this method. This method was reviewed according to the development of 2D materials from graphene, h-BN to transition metal chalcogenides(TMDs) and black phosphorus nanosheets.We discussed the applications of liquid-exfoliated 2D materials including micro- and nanoelectrical devices,photoelectric devices, and energy storage devices.

Flexible high-performance microcapacitors enabled by all-printed two-dimensional nanosheets

Chemically exfoliated nanosheets have exhibited great potential for applications in various electronic devices.Solution-based processing strategies such as inkjet printing provide a low-cost,environmentally friendly,and scalable route for the fabrication of flexible devices based on functional inks of twodimensional nanosheets.In this study,chemically exfoliated high-k perovskite nanosheets(i.e.,Ca_(2)Nb_(3)O_(10)and Ca_(2)NaNb_(4)O_(13))are well dispersed in appropriate solvents to prepare printable inks,and then,a series of microcapacitors with Ag and graphene electrodes are printed.The resulting microcapacitors,Ag/Ca_(2)Nb_(3)O_(10)/Ag,graphene/Ca_(2)Nb_(3)O_(10)/graphene,and graphene/Ca_(2)NaNb_(4)O_(13)/graphene,demonstrate high capacitance densities of 20,80,and 150 nF/cm^(2) and high dielectric constants of 26,110.and 200,respectively.Such dielectric enhancement in the microcapacitors with graphene electrodes is possibly attributed to the dielectric/graphene interface.In addition,these microcapacitors also exhibit good insulating performance with a moderate electrical breakdown strength of approximately 1 MV/cm,excellent flexibility,and thermal stability up to 200℃.This work demonstrates the potential of high-k perovskite nanosheets for additive manufacturing of flexible high-performance dielectric capacitors.