异质结
单层
表面光电压
光致发光
光诱导电荷分离
X射线光电子能谱
化学
载流子
光电子学
紫外光电子能谱
开尔文探针力显微镜
分析化学(期刊)
紫外线
显微镜
光谱学
材料科学
半导体
光催化
电子
电化学
纳米技术
光化学
激子
耗尽区
共价键
电子能带结构
电荷(物理)
载流子寿命
作者
Quanzhen Huang,Z. Wang,R. Liu,Hanyu Yao,Chenwei Ni,Tianyu Bo,Shu Wu,Fusai Sun,范峰滔,Michael V. Mirkin
摘要
Covalently bonded in-plane two-dimensional (2D) transition metal dichalcogenide (TMD) heterojunctions with atomically sharp interfaces hold great promise for photocatalytic applications in solar energy conversion and environmental remediation; however, their spatially resolved charge distribution and transport, particularly under operando conditions, remain poorly understood. Here, we employ photoscanning electrochemical microscopy (photo-SECM) to directly visualize photoinduced charge separation in monolayer MoS2-WS2 in-plane heterojunctions. Spatial separation of photogenerated carriers is observed, with electrons accumulating in MoS2 and holes in WS2, leading to strongly asymmetric interfacial kinetics: Fc+ reduction proceeds rapidly on MoS2 (0.6 cm s-1), whereas Fc oxidation on WS2 is significantly slower (0.008 cm s-1). High-resolution surface photovoltage microscopy (SPVM) enables a quantitative comparison of charge-separation capacity across architectures. The in-plane MoS2-WS2 heterojunction shows the largest photovoltage contrast (-35 mV in MoS2, 20 mV in WS2), exceeding the vertical heterojunction (-18 mV in MoS2, 11 mV in WS2) and the individual monolayers (-12 mV for MoS2, - 1 mV for WS2), establishing the following trend: in-plane > vertical > monolayers. Ultraviolet photoelectron spectroscopy (UPS) indicates that this directional charge separation is driven by intrinsic type-II band alignment, while photoluminescence (PL) imaging shows that the interface acts as a recombination center that limits efficient carrier extraction. These results provide direct experimental evidence of type-II-driven charge separation in in-plane heterojunctions and offer critical insights for interface design in high-efficiency photocatalytic and optoelectronic systems.
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