Kong Bingyin, Pan Gencai, Wang Mengke, Tang Hongye, Lv Zhipeng, Sun Shiyu, Luo Yuxin, You Wenwu, Xu Wen, Mao Yanli
Key Laboratory for High Efficiency Energy Conversion Science and Technology of Henan Province, International Joint Research Laboratory of New Energy Materials and Devices of Henan Province, School of Physics and Electronics, Henan University, Kaifeng, 475004, P. R. China.
Key Laboratory of New Energy and Rare Earth Resource Utilization of State Ethnic Affairs Commission, School of Physics and Materials Engineering, Dalian Minzu University, Dalian, 116600, P. R. China.
Adv Sci (Weinh). 2025 Mar;12(9):e2415473. doi: 10.1002/advs.202415473. Epub 2025 Jan 13.
Multimode luminescent materials exhibit tunable photon emissions under different excitation or stimuli channels, endowing them high encoding capacity and confidentiality for anti-counterfeiting and encryption. Achieving multimode luminescence into a stable single material presents a promising but remains a challenge. Here, the downshifting/upconversion emissions, color-tuning persistent luminescence (PersL), temperature-dependent multi-color emissions, and hydrochromism are integrated into Er ions doped CsNaYbCl nanocrystals (NCs) by leveraging shallow defect levels and directed energy migration. The resulting NCs display strong static and dynamic colorful luminescence in response to ultraviolet, 980-nm laser, and X-ray. Additionally, the NCs exhibit distinct luminescent colors as the temperature increases from 330 to 430 K. Surprisingly, it also demonstrates the ability of the reversible emission modal and color in response to water. Theoretical calculations and experimental characterizations reveal that self-trapped exciton state (STEs), chlorine vacancy defects, and ladderlike 4f energy levels of Er ions contribute to multimodal luminescence. More importantly, it has extremely remarkable environmental stability, which can be stored in the air for more than 18 months, showing promising commercial prospects. This work not only gives new insights into lanthanide-based metal halide NCs but also provides a new route for developing multimodal luminescent nanomaterials for anti-counterfeiting and encryption.
多模发光材料在不同的激发或刺激通道下表现出可调节的光子发射,赋予它们用于防伪和加密的高编码能力和保密性。将多模发光集成到一种稳定的单一材料中是很有前景的,但仍然是一个挑战。在此,通过利用浅缺陷能级和定向能量迁移,将下转换/上转换发射、颜色可调的长余辉发光(PersL)、温度依赖的多色发射和水致变色集成到掺铒的CsNaYbCl纳米晶体(NCs)中。所得的纳米晶体在紫外光、980纳米激光和X射线照射下显示出强烈的静态和动态彩色发光。此外,随着温度从330 K升高到430 K,纳米晶体呈现出不同的发光颜色。令人惊讶的是,它还展示了对水响应的可逆发射模式和颜色的能力。理论计算和实验表征表明,自陷激子态(STE)、氯空位缺陷和铒离子的阶梯状4f能级有助于多模发光。更重要的是,它具有极其显著的环境稳定性,可在空气中储存超过18个月,显示出广阔的商业前景。这项工作不仅为基于镧系元素的金属卤化物纳米晶体提供了新的见解,也为开发用于防伪和加密的多模发光纳米材料提供了一条新途径。
