机构地区:[1]南京邮电大学信息材料与纳米技术研究院,先进生物与化学制造协同创新中心,有机电子与信息显示国家重点实验室培育基地,南京210023 [2]南京工业大学,先进生物与化学制造协同创新中心,柔性电子重点实验室,南京211816 [3]南京工程学院机械工程学院,南京211167
出 处:《物理化学学报》2016年第6期1534-1542,共9页Acta Physico-Chimica Sinica
基 金:supported by the National Key Basic Research Program of China(973)(2015CB932202,2012CB933301);National Natural Science Foundation of China(61274065,51173081,61136003,BZ2010043,51372119,51172110,21304047,21373114,21003076);Innovation Team of the Ministry of Education of China(IRT1148);Ministry of Education Humanities and Social Science Research Projects,China(13YJCZH091);Natural Science Foundation of Jiangsu Province,China(BK20141424);Priority Academic Program Development of Jiangsu Provincial Higher Education Institutions,China(YX030001);Ordinary University Graduate Student Practical Innovation Projects of Jiangsu Province,China(SJLX15_0390);Pandeng Project of Nanjing University of Posts and Telecommunications,China(NY214085);Open Foundation from Jilin University;China(IOSKL2015KF32)~~
摘 要:以芴为原料,以钯为催化剂一步合成了2-(9-苯基芴基)-9,9′螺二芴(PF-SBF)。以PF-SBF作为有机发光二极管的发光及主体材料(FIrpic为磷光客体)时,观察到了不同于PF-SBF及FIrpic发光的红光带。这分别源于PF-SBF分子间的聚集和发光层/传输层诱导的激基复合物。通过选择合适的空穴和电子传输层,有效抑制了激基复合物的发光。同时,PF-SBF和TAPC双主体的结构不仅实现了纯FIrpic和Ir(ppy)_3蓝光和绿光,还大幅提升了器件性能。蓝光、绿光器件的最大电流效率和最大亮度分达到16.7、50.5 cd?A^(-1)和7857 cd?m^(-2)(11 V)、23390 cd?m^(-2)(8 V)。另外,除了PF-SBF,利用相似的合成方法,我们也合成了2-(9-苯基芴基)-9,9′螺芴氧杂蒽(PF-SFX),其较大的三线态能级(2.8 eV)较PF-SBF更适合做蓝光主体。以TAPC和PFSFX为双主体的器件最大电流效率提升到了22.6 cd?A^(-1)。所有实验结果均表明,PF-SBF和PF-SFX是构建高效绿光/蓝光磷光主体材料的有效结构单元。Employing fluorene as substrate,we synthesized a new spirobifluorene derivative,2′-(9-phenylfluoren-9-yl)-9,9′-spirobi[fluorene](PF-SBF),through a one-step palladium-catalyzed cross-coupling reaction.Utilizing PF-SBF as an emitter and as a host of the blue phosphor bis(3,5-difluoro-2-(2-pyridyl)phenyl-(2-carboxypyri-dyl))iridium(III)(FIrpic) in organic light-emitting devices(OLEDs),we observed a red light band different from the intrinsic blue emission of PF-SBF and FIrpic.This was attributed to the intermolecular aggregation of PF-SBF and to exciplexes generated at the interfaces of the emitting layer and the electron transport layer.The exciplex emission was then restrained through a suitable selection of hole and electron transport layer.Employing PF-SBF with di-[4-(N,N-ditolyl-amino)-phenyl]cyclohexane(TAPC) as a cohost,we obtained high-performance blue and green emissions from FIrpic and tris(2-phenylpyridine)iridium(III)(Ir(ppy)3).The maximum current efficiencies and luminances of the blue and green OLEDs were as high as 16.7 and 50.5cd?A^(-1) and 7857(at 11 V) and 23390 cd?m^(-2)(at 8 V),respectively.As an alternative to PF-SBF,we also synthesized a new xanthene derivative,2-(9-phenyl-fluoren-9-yl)spiro[fluorene-9,9′-xanthene](PF-SFX),with a large triplet energy level of 2.8 e V.Using PF-SFX similarly as a host of FIrpic,the current efficiency and luminance were significantly improved to 22.6 cd?A^(-1) and 6421 cd?m^(-2)(at 10 V).These results demonstrate the potential of PF-SBF and PF-SFX as new building blocks for high-efficiency green/blue phosphorescent host materials.
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