纳米尺寸对 CeO2 中光激发极子衰变动力学的影响

IF 8 2区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY Advanced Optical Materials Pub Date : 2024-09-19 DOI:10.1002/adom.202401386
Abhishek Katoch, Sang Han Park, Kwangsik Jeong, Masoud Lazemi, Ru-Pan Wang, Hyun S. Ahn, Tae Kyu Kim, Frank M.F. de Groot, Soonnam Kwon
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引用次数: 0

摘要

复杂材料中的极子动力学研究因其对催化、固态器件和能量存储等各种技术应用的影响而备受关注。本文利用时间分辨 X 射线吸收光谱研究了二氧化铈(CeO2)中的光激发电子和空穴极子动力学,重点研究了纳米尺寸效应。此外,还利用密度泛函理论和多重计算揭示了二氧化铈单晶(SC)和纳米晶(NC)中的光激发极子动力学。观察到电子极子衰减到一个深阱中,持续时间很短≈5 ps,而电子在阱中的停留时间超过 1400 ps。最重要的观察结果是 NC 中空穴的行为,与 SC(10 ps)相比,NC 中空穴的停留时间往往更长(≈150 ps),这表明空穴更多地是存在于表面而非主体。电子极子的快速解离、费米级以上电子寿命的延长以及表面空穴寿命的增强被认为是影响 CeO2 高反应活性的各种因素之一。
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Nano-Size Effects on Decay Dynamics of Photo-Excited Polarons in CeO2
The study of polaron dynamics in complex materials has garnered significant attention owing to its implications for various technological applications, including catalysis, solid-state devices, and energy storage. This paper investigates the photo-excited electron and hole polaron dynamics in cerium dioxide (CeO2) using time-resolved X-ray absorption spectroscopy, with an emphasis on the nano-size effect. Additionally, density functional theory and multiplet calculations have been utilized to reveal the photo-excited polaron dynamics in CeO2 single crystal (SC) and nanocrystal (NC). The electron polaron is observed to decay into a deep trap site with a short duration of ≈5 ps, while electrons in the traps stay for more than 1400 ps. The most significant observation is the behavior of holes in NC, which tends to stay longer (≈150 ps) compared to SC (<10 ps) suggesting hole existence more at the surface than at bulk. The fast dissociation of the electron polarons the prolonged lifetime of the electrons above the Fermi level and the enhanced hole lifetime at the surface are proposed to be among the various factors that influence the high reactivity of CeO2.
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来源期刊
Advanced Optical Materials
Advanced Optical Materials MATERIALS SCIENCE, MULTIDISCIPLINARY-OPTICS
CiteScore
13.70
自引率
6.70%
发文量
883
审稿时长
1.5 months
期刊介绍: Advanced Optical Materials, part of the esteemed Advanced portfolio, is a unique materials science journal concentrating on all facets of light-matter interactions. For over a decade, it has been the preferred optical materials journal for significant discoveries in photonics, plasmonics, metamaterials, and more. The Advanced portfolio from Wiley is a collection of globally respected, high-impact journals that disseminate the best science from established and emerging researchers, aiding them in fulfilling their mission and amplifying the reach of their scientific discoveries.
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