光激发
石墨烯
光探测
光电子学
多激子产生
载流子
物理
载流子散射
声子
光子
散射
电子
材料科学
太赫兹辐射
原子物理学
光电探测器
带隙
纳米技术
光学
凝聚态物理
激发态
量子力学
作者
Klaas‐Jan Tielrooij,Justin C. W. Song,Søren A. Jensen,Alba Centeno,Amaia Pesquera,Amaia Zurutuza Elorza,Mischa Bonn,Leonid Levitov,Frank H. L. Koppens
出处
期刊:Nature Physics
[Nature Portfolio]
日期:2013-02-24
卷期号:9 (4): 248-252
被引量:633
摘要
The conversion of light into free electron–hole pairs constitutes the key process in the fields of photodetection and photovoltaics. The efficiency of this process depends on the competition of different relaxation pathways and can be greatly enhanced when photoexcited carriers do not lose energy as heat, but instead transfer their excess energy into the production of additional electron–hole pairs through carrier–carrier scattering processes. Here we use optical pump–terahertz probe measurements to probe different pathways contributing to the ultrafast energy relaxation of photoexcited carriers. Our results indicate that carrier–carrier scattering is highly efficient, prevailing over optical-phonon emission in a wide range of photon wavelengths and leading to the production of secondary hot electrons originating from the conduction band. As hot electrons in graphene can drive currents, multiple hot-carrier generation makes graphene a promising material for highly efficient broadband extraction of light energy into electronic degrees of freedom, enabling high-efficiency optoelectronic applications. The efficiency of carrier–carrier scattering in graphene is now experimentally demonstrated. The dominance of this mechanism over phonon-related scattering means that a single high-energy photon could create two or more electron–hole pairs in graphene; an effect useful for optoelectronic applications.
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