发光
膜
液晶
光子上转换
材料科学
钙钛矿(结构)
Crystal(编程语言)
光电子学
光学
结晶学
化学
物理
计算机科学
生物化学
程序设计语言
作者
Yuyang Pu,Xuebing Wen,Haotian Gu,Huilong Zhu,Ming Yuan,Jia‐Qi Huang,Qiuqiang Zhan,Xiaofang Jiang,Lakshminarayana Polavarapu,Xiaowen Hu,Guofu Zhou
标识
DOI:10.1016/j.cej.2025.162515
摘要
• Record-high g-factor (1.80) achieved in perovskite-based UC-CPL systems. • Flexible membrane enables wearable and bendable photonic device integration. • FsLDW creates high-precision microscale patterns for secure optical encoding. • Dual-mode emission with color shifts boosts anti-counterfeiting performance. Upconversion circularly polarized luminescence (UC-CPL) which refers to the emission of circularly polarized light upon excitation with low-energy photons through photon upconverion process, has garnered significant attention due to its distinctive photonic properties. However, achieving high dissymmetry factors for UC-CPL through a simple thin-film design remains a challenge. Here, a flexible UC-CPL membrane device is reported, consisting of a composite film of upconversion nanoparticles (UCNPs) and perovskite nanocrystals (PNCs) integrated with a cholesteric liquid crystal (CLC) polymer film. The UCNPs and PNCs composite was synthesized via a one-step in-situ method, facilitating efficient nonradiative Förster resonance energy transfer (FRET) from UCNPs to PNCs, as evidenced by the shortened time-resolved fluorescence decay lifetime of the UCNPs. By designing the CLC film with a photonic bandgap that matches the emission peak of the PNCs, a UC-CPL with a dissymmetry factor of 1.8 was achieved. This is attributed to the circular polarization selection characteristics induced by the periodic helical structure of the CLC. The membrane device is fully solution-processable and exhibits ultra-flexibility as the emission intensity remains unchanged after repeated 300 bending cycles. Microscale pattern was inscribed on the membrane using femtosecond laser direct writing (FsLDW), and the pattern, with dual-mode CPL capability, exhibit distinct colors under different excitation wavelengths and reading modes. These findings represent the demonstration of perovskite based UC-CPL from a flexible membrane device with a high g lum , providing valuable insights for practical applications for micro/nano-scale optical information encryption and anti-counterfeiting.
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