皮秒
超短脉冲
极化子
材料科学
激发
激发态
化学物理
氧化物
过渡金属
超快激光光谱学
扩散
光电子学
光激发
太赫兹辐射
电子迁移率
凝聚态物理
太赫兹光谱与技术
光开关
光子学
菲克扩散定律
分子物理学
载流子
瞬态(计算机编程)
纳米光子学
作者
Keming Li,Yingjie Wang,Lan Jiang,Guoquan Gao,Guanzhao Wen,Yan Zhang,Xianjie Wang,Shuaifeng Lou,Mischa Bonn,Hai I Wang,Tong Zhu
标识
DOI:10.1038/s41467-025-66193-x
摘要
Abstract The intrinsically low carrier mobility of transition metal oxides within the polaron transport framework fundamentally limits their optoelectronic performance. Although optical transitions profoundly impact carrier generation and transport dynamics in oxide systems, the underlying mechanisms remain elusive. Here we demonstrate that the nature of optical transitions decisively regulates hot-hole transport in representative oxides, Co 3 O 4 and α-Fe 2 O 3 . Combining ultrafast optical nanoscopy with terahertz spectroscopy, we identify two distinct regimes: rapid band-like transport of energetic holes within a few picoseconds (~100 cm 2 s -1 ) and slower polaron-dominated hopping transport (~10 -3 cm 2 s -1 ) thereafter. Both the oxide composition and the transition pathway play critical roles in tailoring sub-picosecond hot-carrier dynamics. In Co 3 O 4 , metal-to-metal excitation at 1.55 eV yields an ultrahigh diffusion constant of 290 cm 2 s -1 , seven times that generated by higher-energy ligand-to-metal transitions (2.58 eV). These findings underscore the pivotal role of transient hot-carrier dynamics and suggest optical control of excited states as a promising route for optimizing energy management in oxide-based optoelectronic and photocatalytic systems.
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