极化子
量子点
材料科学
光致发光
光电子学
碲化镉光电
斯托克斯位移
带隙
量子产额
硒化镉
自发辐射
纳米晶
荧光
宽带
纳米技术
载流子
激子
格子(音乐)
量子
发射光谱
光发射
光子学
生物成像
凝聚态物理
分子物理学
电荷(物理)
发光二极管
作者
Qi Xu,Yijie Hou,Shuaiqi Li,Maohua Chen,Fuqiang Ren,Yannan Liu,C L Zhang,Tesen Zhang,Dongbo Guo
摘要
ABSTRACT Despite widespread attention in near‐infrared IIb/c (NIR‐IIb/c, 1500–2000 nm) fluorescence for deep‐tissue bioimaging, the development of NIR‐IIb/c emissive materials with high photoluminescence quantum yield (PLQY) remains hindered by the energy gap law (EG law). Herein, we propose a polaron engineering strategy to circumvent the EG law via accelerating the radiative recombination rate by 150‐fold through increased charge localization. By incorporating Nd 3+ into CdTe quantum dot lattice, we achieved broadband NIR‐IIb/c emission peak at 1730 nm, with PLQY of 11.34 ± 0.79% in aqueous solution and a Stokes shift exceeding 900 nm. We demonstrate Nd 3+ substitution introduces beneficial defects that perturb electronic structure and local symmetry. Upon 808 nm excitation, these defects trap photoexcited carriers, inducing lattice distortions and strong electron‐phonon coupling, which leads to the formation of polarons with high NIR‐II emission efficiency. The resulting QDs enable clinical‐grade NIR‐II imaging via dual modes, including low‐power (10 mW cm − 2 ) real‐time deep‐tissue imaging and white‐light‐activatable fluorescence‐guided surgery navigation. This study provides a promising approach to bypass the EG law, offering a pathway toward highly emissive emitters in the NIR regime.
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