Slowing hot-electron relaxation in mix-phase nanowires for hot-carrier photovoltaics

doi:10.1021/acs.nanolett.1c02725

	Slowing hot-electron relaxation in mix-phase nanowires for hot-carrier photovoltaics
	Wang, Hailu 1,8; Wang, Fang 1,8; Xu, Tengfei 1,6; Xia, Hui 1,8; Xie, Runzhang 1,8; Zhou, Xiaohao 1,8; Ge, Xun 1,5; Liu, Weiwei 1,8; Zhu, Yicheng 1,8; Sun, Liaoxin 1,8; Guo, Jiaxiang 1,8; Ye, Jiafu 1,8; Zubair, Muhammad 1,8; Luo, Man4 ; Yu, Chenhui 4; Sun, Deyan 5; Li, Tianxin 1,8; Zhuang, Qiandong 2; Fu, Lan 3; Hu, Weida 1,8; Lu, Wei1,7,8
	2021-09-22
发表期刊	NANO LETTERS (IF:9.6[JCR-2023],10.1[5-Year])
ISSN	15306984
EISSN	15306992
卷号	21 期号:18 页码:7761-7768
发表状态	已发表
DOI	10.1021/acs.nanolett.1c02725
摘要	Hot carrier harvest could save 30% energy loss in solar cells. So far, however, it is still unreachable as the photoexcited hot carriers are short-lived, 1 ps, determined by a rapid relaxation process, thus invalidating any reprocessing efforts. Here, we propose and demonstrate a feasible route to reserve hot electrons for efficient collection. It is accomplished by an intentional mix of cubic zinc-blend and hexagonal wurtzite phases in III-V semiconductor nanowires. Additional energy levels are then generated above the conduction band minimum, capturing and storing hot electrons before they cool down to the band edges. We also show the superiority of core/shell nanowire (radial heterostructure) in extracting hot electrons. The strategy disclosed here may offer a unique opportunity to modulate hot carriers for efficient solar energy harvest. © 2021 American Chemical Society.
关键词	Electrons Energy dissipation III V semiconductors Nanowires Solar cells Solar energy Zinc sulfide Conduction band minimum Core/shell nanowires Electron relaxation Hexagonal wurtzite Photovoltaics Radial heterostructure Rapid relaxation process Semiconductor nanowire mix-phase nanowire hot electrons InAs radial heterostructure photovoltaics
收录类别	SCIE ; EI
语种	英语
WOS研究方向	Chemistry ; Science & Technology - Other Topics ; Materials Science ; Physics
WOS类目	Chemistry, Multidisciplinary ; Chemistry, Physical ; Nanoscience & Nanotechnology ; Materials Science, Multidisciplinary ; Physics, Applied ; Physics, Condensed Matter
WOS记录号	WOS:000700883900045
出版者	American Chemical Society
EI入藏号	20213710889087
EI主题词	Hot electrons
EI分类号	525.4 Energy Losses (industrial and residential) ; 657.1 Solar Energy and Phenomena ; 701.1 Electricity: Basic Concepts and Phenomena ; 702.3 Solar Cells ; 761 Nanotechnology ; 804.2 Inorganic Compounds ; 933 Solid State Physics
原始文献类型	Journal article (JA)
引用统计	正在获取...
文献类型	期刊论文
条目标识符	https://kms.shanghaitech.edu.cn/handle/2MSLDSTB/133183
专题	物质科学与技术学院_博士生物质科学与技术学院_特聘教授组_陆卫组
通讯作者	Xia, Hui; Hu, Weida; Lu, Wei
作者单位	1.State Key Laboratory of Infrared Physics, Shanghai Institute of Technical Physics, Chinese Academy of Sciences, 500 Yutian Road, Shanghai; 200083, China; 2.Department of Physics, Lancaster University, Lancaster; LA1 4YB, United Kingdom; 3.Department of Electronic Materials Engineering, Research School of Physics, Australian National University, Canberra; Australian Capital Territory; 2601, Australia; 4.Jiangsu Key Laboratory of ASIC Design, School of Information Science and Technology, Nantong University, Nantong; 26019, China; 5.Department of Physics, East China Normal University, Shanghai; 200241, China; 6.Frontier Institute of Chip and System, Fudan University, Shanghai; 200438, China; 7.School of Physical Science and Technology, ShanghaiTech University, Shanghai; 201210, China; 8.University of Chinese Academy of Sciences, Beijing; 100049, China
通讯作者单位	物质科学与技术学院
推荐引用方式 GB/T 7714	Wang, Hailu,Wang, Fang,Xu, Tengfei,et al. Slowing hot-electron relaxation in mix-phase nanowires for hot-carrier photovoltaics[J]. NANO LETTERS,2021,21(18):7761-7768.
APA	Wang, Hailu.,Wang, Fang.,Xu, Tengfei.,Xia, Hui.,Xie, Runzhang.,...&Lu, Wei.(2021).Slowing hot-electron relaxation in mix-phase nanowires for hot-carrier photovoltaics.NANO LETTERS,21(18),7761-7768.
MLA	Wang, Hailu,et al."Slowing hot-electron relaxation in mix-phase nanowires for hot-carrier photovoltaics".NANO LETTERS 21.18(2021):7761-7768.