二维过渡金属硫族化合物中的缺陷和相关载流子动力学的研究进展 -

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二维过渡金属硫族化合物中的缺陷和相关载流子动力学的研究进展

doi:10.37188/CO.2020-0106

王云坤^1,,
李耀龙^1,,
高宇南^{1, 2,,}

1.
北京大学物理学院人工微结构和介观物理国家重点实验室，北京 100871
2.
北京大学纳光电子前沿科学中心，北京 100871

基金项目:国家重点研发计划（No. 2018YFA0306302）；国家自然科学基金委面上项目（No. 61875002）

详细信息

作者简介:
王云坤（1996—），男，山东济南人，北京大学物理学院博士研究生，2018年于山东师范大学获得学士学位，主要从事二维材料及其异质结的光电性质研究。E-mail：wyk@pku.edu.cn
李耀龙（1992—），男，河南周口人，北京大学物理学院博士研究生，2016年于南开大学获得学士学位，主要从事二维材料及微纳光子学的研究。E-mail：yaolong@pku.edu.cn
高宇南（1983—），男，山西阳泉人，博士，北京大学物理学院研究员，博士生导师，2012年于荷兰代尔夫特理工大学获得博士学位，2012年至2014年在中国科学院物理研究所从事博士后研究，2014年至2017年在美国麻省理工学院从事博士后研究，主要从事低维材料与光电子学的研究。E-mail：gyn@pku.edu.cn

中图分类号:O474; O472+.3
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出版历程
- 收稿日期:2020-06-15
- 修回日期:2020-07-27
- 网络出版日期:2021-01-05
- 刊出日期:2021-01-25

Progress on defect and related carrier dynamics in two-dimensional transition metal chalcogenides

1.
State Key Laboratory for Artificial Microstructure and Mesoscopic Physics, School of Physics, Peking University, Beijing 100871, China
2.
Frontiers Science Center for Nano-optoelectronics, Peking University, Beijing 100871, China

Funds:Supported by National Key Research and Development Project (No. 2018YFA0306302); National Natural Science Foundation of China (No. 61875002)

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Corresponding author:gyn@pku.edu.cn

摘要

摘要:原子级厚度的单层或者少层二维过渡金属硫族化合物因其独特的物理特性而被寄希望成为下一代光电子器件的重要组成部分。然而，二维材料的缺陷在很大程度上影响着材料的性质。一方面，缺陷的存在降低了材料的荧光量子效率、载流子迁移率等重要参数，影响了器件的性能。另一方面，合理地调控和利用缺陷催生了单光子源等新的应用，因此，表征、理解、处理和调控二维材料中的缺陷至关重要。本文综述了二维过渡金属硫族化合物中的缺陷以及缺陷相关的载流子动力学研究进展，旨在梳理二维材料中的缺陷及其超快动力学与材料性能之间的关系，为二维过渡金属硫族化合物材料特性和高性能光电子器件的相关研究提供支持。
- 二维材料/
- 过渡金属硫族化合物/
- 缺陷/
- 载流子动力学
Abstract:Because of their unique physical properties, the monolayer and few-layer two-dimensional transition metal chalcogenides with atomic-level thickness are expected to play an important role in the next generation of optoelectronic devices. However, defects in two-dimensional materials affect their properties to a great extent. On one hand, defects reduce the fluorescence quantum efficiency, carrier mobility and other important device parameters. On the other hand, the control and utilization of defects have given birth to new techniques such as using single-photon sources. Therefore, it is very important to characterize, understand, handle and control the defects in two-dimensional materials. In this review, the research progress on defects and its related carrier dynamics in two-dimensional transition metal chalcogenides is summarized. This paper aims to sort out the great influence of defects and their related ultrafast dynamics on material performance in two-dimensional transition metal chalcogenides, and to support studies on fundamental physical properties and high-performance optoelectronic devices.
- two-dimensional materials/
- transition metal chalcogenides/
- defects/
- carrier dynamics

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图 1二维TMDCs中点缺陷的高分辨表征。（a−f） STEM-ADF对MoS₂中6种点缺陷的表征^[85]；（g−j）4种常见的TMDCs材料中缺陷的STM表征，深蓝色的点代表原子缺失或存在受体杂质，亮黄色的点代表存在给体杂质^[86]；（k）新制备的MoS₂与（l）在大气中放置8个月后的光学显微镜照片的对比^[90]；（m−t）超高分辨STM和非接触式AFM对WS₂中点缺陷的表征^[88]

Figure 1.High resolution characterization of point defects in 2D TMDCs. (a−f) STEM-ADF characterization of six kinds of point defect in MoS₂^[85]; (g−j) STM characterization of defects in four common TMDCs materials, where dark blue points represent atom defects or receptor impurities, bright yellow points represent donor impurities^[86]; comparison of optical microscope pictures between (k) fresh MoS₂and (l) fresh MoS₂after 8 months of atmospheric exposure^[90]; (m−t) ultra-high resolution STM and non-contact AFM characterization of point defects in WS₂^[88]

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图 2缺陷的稳态光谱学研究。（a）电子束、等离子体、紫外光可以在TMDCs中产生缺陷；（b）单层WSe₂随氩等离子体处理时间变化的荧光光谱^[103]；（c）使用氩等离子和电子束处理单层WSe₂后的荧光光谱^[103]；（d）单层MoS₂随电压（上图）、泵浦功率（中图）、温度（下图）改变的荧光光谱^[110]；（e）缺陷捕获激子的模型（上图），束缚态激子/激子发光占比（左侧坐标轴）与带电激子/激子发光占比（右侧坐标轴）随栅压的变化（下图）^[110]；（f）DFT计算得到的存在缺陷的WS₂的能带结构（左图）和跃迁偶极矩（右图）^[115]；（g）（h）随着离子束处理强度增加，单层MoS₂拉曼光谱的变化^[120]；（i）单层WSe₂中缺陷的EL光谱^[130]

Figure 2.Steady state spectroscopic studies of defects. (a) The defects can be produced in TMDCs by electron beam, plasma and ultraviolet irradiation; (b) fluorescence spectrum of monolayer WSe₂as it changes with varying argon plasma treatment^[103]; (c) fluorescence spectrum of monolayer WSe₂after argon plasma and electron beam treatment^[103]; (d) fluorescence spectrum of monolayer MoS₂as it changes with voltage (above), pump power (center) and temperature (below)^[110]; (e) defect capture exciton model (above), the bound exciton/exciton PL intensity ratio (left axis) and the trion/exciton PL intensity ratio (right axis) vary with the gate voltage (below)^[110]; (f) band structure (left) and the transition dipole moment (right) of defected monolayer WS₂calculated by DFT^[115]; (g)(h) Raman spectrum of monolayer MoS₂with respect to ion beam treatment intensity^[120]; (i) electroluminescence spectra of defects in monolayer WSe₂^[130]

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图 3缺陷态发光的抑制。（a）使用“超级酸”处理单层MoS₂并使用含氟聚合物进行封装^[134]；（b）使用“超级酸”处理单层MoS₂前后的荧光光谱^[134]；（c）使用静电掺杂调节单层MoS₂的PLQY的器件结构和原理图^[142]；（d）改变栅压和泵浦功率时MoS₂的PLQY的变化^[142]；（e）使用照射处理MoS₂的示意图（上图）和发生的氧气物理吸附与化学吸附（下图）^[146]；（f）对久置的MoS₂进行照射时荧光光谱随照射时间的变化^[147]

Figure 3.Suppression of defect state luminescence. (a) Treating the monolayer MoS₂with "super acid" and encapsulating it with CYTOP^[134]; (b) fluorescence spectrum before and after treatment^[134]; (c) device structure and schematic diagram of PLQY tuning of the monolayer MoS₂through electrostatic doping^[142]; (d) PLQY of monolayer MoS₂changes with the gate voltage and pump power^[142]; (e) schematic diagram of the MoS₂treated by laser irradiation (above) and occurred oxygen physisorption and chemisorption (below)^[146]; (f) fluorescence spectrum of aged MoS₂changing with time irradiated by laser^[147]

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图 4(a) TMDCs中的载流子动力学和(b)缺陷捕获过程

Figure 4.(a) Carrier dynamics and (b) defect capture process in TMDCs

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图 5基于瞬态吸收光谱对TMDCs缺陷相关的载流子动力学的研究。（a）使用泵浦-探测方法对缺陷态进行探测的示意图；（b）泵浦光和探测光打在样品的相同位置，两束光通过位移台改变到达的时间差^[62]；（c）缺陷捕获载流子的快通道（左图）和慢通道（右图）的示意图^[62]；（d）不同温度下单层MoS₂对探测光的透射率随时间的变化^[62]；（e）不同功率下少层MoTe₂载流子寿命的变化^[63]；（f）不同功率下单层MoSe₂对探测光的反射率随时间的变化^[159]

Figure 5.Studies on defect related carrier dynamics of TMDCs based on transient absorption spectroscopy. (a) Schematic diagram of detecting the defect state by using the pump-probe method; (b) pump light and the probe light illuminate the same position of the sample. The time difference of two light beams changing through optical path difference^[62]; (c) schematic diagram of the fast channel (left) and the slow channel (right) of the defect trapping process^[62]; (d) the transmittance of the monolayer MoS₂to the probe light varying with time under different temperatures^[62]; (e) change of carrier lifetime of MoTe₂at different pump powers^[63]; (f) change in reflectivity of the monolayer MoSe₂with respect to time at different pump powers^[159]

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图 6基于时间分辨荧光光谱对TMDCs缺陷相关的载流子动力学的研究。 (a)时间分辨荧光对缺陷态进行探测的原理图；(b)本征WS₂自由激子的荧光衰减曲线^[157]；(c)使用氩离子束轰击产生缺陷后WS₂的自由激子（蓝线）和束缚态激子（红线）的荧光衰减曲线^[157]；(d)使用对单层WS₂进行预处理后（圆圈区域），高功率（上图）和低功率（下图）的荧光强度对比，两张图中的强度都用各图的最高强度进行了归一化^[148]；(e)单层WS₂的荧光在不同激发功率下的荧光衰减曲线，蓝线为预先使用照射，红色为未提前处理^[148]

Figure 6.Studies of defect-related carrier dynamics in TMDCs using TRPL spectroscopy. (a) Schematic diagram of TRPL to detect the defect state; (b) PL decay curve of free exciton energy in pristine monolayer WS₂^[157]; (c) PL decay curves of the free exciton (blue line) and the bound exciton (red line) energy in the defective monolayer WS₂after being irradiated by an argon ion beam^[157]; (d) comparison of the PL intensities of the monolayer WS₂pretreated by laser (circle area) at a high pump power (above) and a low pump power (below)^[148]; (e) PL decay curve of the monolayer WS₂under different excitation powers. The blue line represents the sample before being irradiated by laser, and the red line presents that not having been pretreated^[148]

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图 7基于时间分辨ARPES和PEEM对TMDCs缺陷相关的载流子动力学的研究。 (a)时间分辨ARPES和PEEM对缺陷态进行探测的原理图；(b)时间分辨ARPES对动量空间进行探测的原理图^[175]；(c)时间分辨PEEM对样品表面光电子成像的原理图^[64]；(d)理论计算得到的MoS₂的动量空间与探测的动量区域（灰色阴影）（上图），时间分辨APRES实验测得的动量空间不同位置光电子发射信号的上升和下降时间^[161]；(e)脉冲光激发后MoS₂动量空间谷间散射和缺陷捕获的示意图^[161]；(f)泵浦探测零时刻PEEM对单层WS₂的实空间成像（上图），三种覆盖单层WS₂的不同区域的光电子发射信号强度（下图）^[64]；(g)三种区域光电子发射信号强度随时间的变化^[64]；(h)光电子发射信号强度的能量分布随泵浦探测时间差的变化^[64]

Figure 7.Study of defect related carrier dynamics in TMDCs based on time-resolved ARPES and PEEM. (a) Schematic diagram of time-resolved ARPES and PEEM for detecting the defect state; (b) schematic diagram of time-resolved ARPES for detecting momentum space^[175]; (c) schematic diagram of time-resolved PEEM for photoelectron imaging of the sample surface^[64]; (d) momentum space of the MoS₂calculated by theoretcally. The detectable momentum area (gray shadow) (above). Characteristic photo emission intensity rise times and fall times as a function of momentum (below)^[161]; (e) schematic diagram of intervalley scattering and defect trapping process of hot electrons in the momentum space of MoS₂after being excitated by optical pulse^[161]; (f) PEEM image of the WS₂at a 0 ps time delay (above), photoelectron intensity along the yellow cross-cut line (below)^[64]; (g) photoelectron emission intensities as a function of the time delay in the three regions^[64]; (h) variation of energy distribution of photoelectron emission intensity at different pump-probe time delay^[64]

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图 8（a）使用“超级酸”处理后单层MoS₂中激子的时间衰减与空间扩散^[176]；（b）不同介电环境单层WS₂的激子扩散率与荧光寿命的关系^[156]

Figure 8.(a) Exciton diffusion in monolayer MoS₂after super acid treatment^[176]; (b) The relationship between diffusion coefficient and PL lifetime of monolayer WS₂under different dielectric environments^[156]

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图 9TMDCs缺陷对谷间散射的影响。（a）理论计算得到的MoSe₂的偏振荧光光谱，使用右旋光（蓝色）激发，得到左旋光和右旋光（红色）的荧光^[79]；（b） WSe₂束缚态激子的积分荧光光谱和不同光子能量的谷偏振度^[78]；（c）WSe₂束缚态激子瞬态荧光和谷偏振度随时间的变化^[78]

Figure 9.The effect of defects on intervalley scattering in TMDCs. (a) Calculated PL spectrum of MoSe₂excited by right-handed light (blue line), observing PL from the left and the right (red line)^[79]; (b) integrated PL spectrum of bound exciton in defective WSe₂and their degree of valley polarization^[78]; (c) decay of PL and valley polarization degree of bound exciton in defective WSe₂^[78]

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