Emerging probing perspective of two-dimensional materials physics:terahertz emission spectroscopyOACSTPCD
Emerging probing perspective of two-dimensional materials physics:terahertz emission spectroscopy
Terahertz(THz)emission spectroscopy(TES)has emerged as a highly effective and versatile technique for investigating the photoelectric properties of diverse materials and nonlinear physical processes in the past few decades.Concurrently,research on two-dimensional(2D)materials has experienced substantial growth due to their atomically thin structures,exceptional mechanical and optoelectronic properties,and the potential for applications in flexible electronics,sensing,and nanoelectronics.Specifically,these materials offer advantages such as tunable bandgap,high carrier mobility,wideband optical absorption,and relatively short carrier lifetime.By applying TES to investigate the 2D materials,their interfaces and heterostructures,rich information about the interplay among photons,charges,phonons and spins can be unfolded,which provides fundamental understanding for future applications.Thus it is timely to review the nonlinear processes underlying THz emission in 2D materials including optical rectification,photon-drag,high-order harmonic generation and spin-to-charge conversion,showcasing the rich diversity of the TES employed to unravel the complex nature of these materials.Typical applications based on THz emissions,such as THz lasers,ultrafast imaging and biosensors,are also discussed.Step further,we analyzed the unique advantages of spintronic terahertz emitters and the future technological advancements in the development of new THz generation mechanisms leading to advanced THz sources characterized by wide bandwidth,high power and integration,suitable for industrial and commercial applications.The continuous advancement and integration of TES with the study of 2D materials and heterostructures promise to revolutionize research in different areas,including basic materials physics,novel optoelectronic devices,and chips for post-Moore's era.
Yifei Wu;Zeli Wang;Pingren Ham;Andrew Hanna;Jiaming Pan;Xinyue Hu;Zhengcao Li;Ji Zhou;Chen Wang;Yuqi Wang;Di Bao;Xiaonan Deng;Simian Zhang;Lin Yu-chun;Shengxian Ke;Jianing Liu;Yingjie Liu
State Key Laboratory of New Ceramics and Fine Processing,Key Laboratory of Advanced Materials of Ministry of Education,School of Materials Science and Engineering,Tsinghua University,100084 Beijing,ChinaState Key Laboratory of New Ceramics and Fine Processing,Key Laboratory of Advanced Materials of Ministry of Education,School of Materials Science and Engineering,Tsinghua University,100084 Beijing,China||Beijing Advanced Innovation Center for Integrated Circuits,100084 Beijing,China
《光:科学与应用(英文版)》 2024 (007)
1278-1298 / 21
C.W.financially supported by the National Key Research and Development Program of China(2021YFA1200800),the National Natural Science Foundation of China(62004114 and 62174098),Tsinghua University Initiative Scientific Research Center,Beijing Municipal Science and Technology Commission(Z221100005822011)and Beijing Advanced Innovation Center.
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