磷光
材料科学
余辉
荧光粉
发光
聚苯乙烯
聚合物
光电子学
工作(物理)
纳米技术
持续发光
共聚物
相(物质)
有机电子学
有机发光二极管
猝灭(荧光)
材料设计
科罗尼
量子效率
数码产品
兴奋剂
作者
Ping Jiang,Chenjia Yin,Qiqi Xu,Jie Sun,Lei Zhou,Lisha Zhang,Yanjie Chen,Bingbing Ding,He Tian,Xiang Ma
摘要
Organic ultralong room-temperature phosphorescence (OURTP) materials are promising for flexible optoelectronics but often suffer from a trade-off between phosphorescence efficiency and mechanical flexibility. To overcome this limitation, a block copolymer system is developed through the incorporation of coronene into poly(styrene-isoprene-styrene) (SIS). Within this structure, the rigid polystyrene (PS) segments immobilize the phosphors and facilitate charge-transfer-mediated OURTP, resulting in high phosphorescence efficiency (Φ = 54.9%, τ = 6.26 s). Concurrently, the polyisoprene (PI) segment ensures outstanding elasticity, endowing the material with ultra-stretchability (2380.5% strain) and fatigue resistance (withstanding 600% strain over 40 cycles). The system also maintains intrinsic morphological homogeneity, effectively avoiding phase separation. Through microphase engineering, this work successfully reconciles the long-standing conflict between luminescence and flexibility, providing a general design strategy for multifunctional polymers suitable for wearable electronics that demand both deformability and phosphorescent capability.
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