双苯乙烯取代噻咯的合成及聚集态诱导发光

聚集态诱导发光(AIE)材料由于克服了有机发光材料常见的聚集态荧光猝灭现象,提高了固体发光效率而引起了研究者的重视,而噻咯(Silole)是具有AIE性质的环状多烯化合物中最具代表性的一种.实验合成了一种双苯基乙烯取代的含硅杂环化合物1,1-二甲基-3,4-二苯基-2,5-二苯基乙烯Silole,并利用核磁共振表征了其结构,表明为目标产物.紫外可见分光光度法测试结果表明吸收峰在380nm处.光致发光测试显示发射峰在420nm处,并通过改变良溶剂和不良溶剂的比例,测试了目标产物的聚集态诱导发光性质.所选用良溶剂/不良溶剂组分别为二氯甲烷/甲醇(甲苯、水)、四氢呋喃/甲醇(甲苯、水).结果表明,该化合物在良溶剂中发光微弱,但在聚集态下具有良好的荧光性能,显示出明显的聚集态诱导发光性质.

1,2,4,5-四{4-[N,N-二(4-碘苯基)氨基]苯乙烯基}苯的聚集诱导发光增强及电存储性质

通过Wittig-Horner反应合成了1个三苯胺共轭树枝分子1,2,4,5-四{4-[N,N-二(4-碘苯基)氨基]苯乙烯基}苯(TPAB-I).TPAB-I在甲苯、四氢呋喃、乙酸乙酯、二氯甲烷和DMF溶液中的最大荧光发射峰分别位于451,464,478,481和511 nm;其固体粉末和旋涂膜的最大发射波长分别为526和488 nm.实验结果表明,TPAB-I具有明显的聚集诱导发光增强效应.将三苯胺共轭树枝分子TPAB-I用于制作有机电存储器件,制得了三明治夹心结构的Al/TPAB-I/ITO电存储器件.该电存储器ON/OFF状态下电流比接近104,擦除电压为-2.0 V,写入电压为1.5 V,在1.0 V的读取电压下,电存储器在104s内均能保持良好的稳定性,具有较好的电存储性能.

聚合物聚集诱导发光体系及机理研究进展

聚集态诱导发光(AIE)现象自2001年被发现以来发展十分迅速,从早期的小分子体系逐渐发展到高分子聚合物体系。与传统的小分子相比,聚合物体系的AIE材料能够克服加工上的难题,为制备高效发光器件创造了良好条件。AIE机理随着体系的开发不断发展,其核心依然是分子聚集态变化导致的辐射跃迁渠道,每一种AIE现象的形成往往需要几个因素协同作用,机理的不断完善一方面很好地解释了现有的AIE现象,另一方面为开发出新的AIE体系奠定了理论基础。本文总结了几种在小分子基础上形成的聚合物AIE体系,并在现有的机理基础上介绍了几种较新的AIE机理。

Self-assembled nanostructured photosensitizer with aggregation-induced emission for enhanced photodynamic anticancer therapy

Three nanostructured photosensitizers with aggregation-induced emission(AIE) characteristics based on2,3-bis(4?-(diphenylamino)-[1,1?-biphenyl]-4-yl) fumaronitrile(BDBF) were prepared for image-guided photodynamic therapy(PDT). BDBF was encapsulated with Pluronic F-127(F127) to form usual spherical nanoparticles(F127@BDBF NPs) with a red fluorescence emission and 9.8% fluorescence quantum yield(FQY). Moreover, BDBF self-assembled into nanorods(BDBF NRs) in water. Compared with F127@BDBF NPs, BDBF NRs exhibited stronger orange fluorescence with a higher FQY of 23.3% and similar singlet oxygen(1O2) generation capability. BDBF NRs were further modified with F127 to form BDBF@F127 NRs with the same 1O2 generation ability as BDBF NRs. The three nanostructures exhibited a higher 1O2 production capacity than BDBF molecule in dissolved state and favorable stability in an aqueous solution as well as under physiological condition. In vitro photocytotoxicity experiments indicated that the three nanostructures inhibited tumor cell proliferation effectively.Therefore, to construct eligible nanostructures with a high FQY and 1O2 generation ability, simple self-assembly can serve as a valuable method to prepare photosensitizers with enhanced PDT.