卤化物
激子
单重态
材料科学
发光
相变
化学物理
过渡金属
光化学
磷光
斯托克斯位移
金属
金属卤化物
光致发光
化学
偶极子
相(物质)
兴奋剂
配位复合体
激发态
结晶学
光子学
荧光粉
发射光谱
原子电子跃迁
光发射
镉
受激发射
光电子学
无机化学
物理化学
热致变色
纳秒
作者
Zhe Tang,Binbin Fan,C. C. Fan,Qingfeng Wei,Dandan Luo,Tingting Xue,Yan Su,Junsheng Chen
摘要
ABSTRACT Reversible control of structural phase transitions and luminescence remains a key challenge in organic–inorganic hybrid metal halides for stimuli‐responsive photonic applications. Here, we report two new zero‐dimensional (0D) Cd‐based metal halides, (DFPD) 6 CdCl 8 and (DFPD) 2 CdCl 4 ·H 2 O (DFPD + = 4,4‐difluoropiperidine), in which Sb 3+ doping enables distinct emission behaviors governed by coordination geometry. Combined spectroscopic studies and theoretical calculations reveal that Sb 3+ ‐doped (DFPD) 6 CdCl 8 exhibits yellow emission with a large Stokes shift arising from triplet self‐trapped exciton ( 3 STE) emission, whereas Sb 3+ ‐doped (DFPD) 2 CdCl 4 ·H 2 O displays excitation‐dependent emission due to competing singlet STE ( 1 STE) and 3 STE states. This contrast originates from the different Cd–Cl coordination environments (octahedral vs. tetrahedral), which modulate the energy levels and transition dipole moments. Importantly, hydrochloric acid (HCl) and 4,4‐difluoropiperidine induce fully reversible interconversion between the two structures, allowing dynamic switching between yellow and deep‐orange emission. Based on this reversible luminescence, we further demonstrated applications in dynamic anti‐counterfeiting and multilevel information encryption. This work establishes a coordination‐structure‐driven strategy for programmable emission in 0D hybrid metal halides.
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