Lee, Jae Yoon Kang, Sungwoo Lee, Donghun Choi, Seokhoon Yang, Seunghoon Kim, Kangwon Kim, Yoon Seok Kwon, Ki Chang Choi, Soo Ho Kim, Soo Min Kim, Jihoon Park, Jungwon Park, Haeli Huh, Woong Kang, Hee Seong Lee, Seong Won Park, Hong-Gyu Ko, Min Jae Cheng, Hyeonsik Han, Seungwu Jang, Ho Won Lee, Chul-Ho 2024-01-19T19:00:55Z 2024-01-19T19:00:55Z 2021-09-05 2019-11 2211-2855 https://pubs.kist.re.kr/handle/201004/119373 Heterojunction catalyst can facilitate efficient photoelectrochemical (PEC) hydrogen evolution by reducing a potential barrier for charge transfer at the semiconductor/electrolyte interface. Such a heterojunction effect at the atomic thickness limit has not yet been explored although it can be strengthened because of strong built-in field and ultrafast charge transfer across the junction. Here, we first investigate a novel strategy to boost the hydrogen evolution performance of the p-type WSe2 photocathode via reducing the overpotential with an atomically thin heterojunction catalyst comprising MoS2 and WS2 monolayers. To unveil an effective role of the heterojunction by isolating its kinetic contribution from other collective catalytic effects, we develop and utilize an in situ scanning PEC microscopy, which enables the spatially-resolved visualization of the enhanced photocatalytic hydrogen evolution performance of the heterojunction. Notably, significant reduction in overpotential, from +0.28 +/- 0.03 to -0.04 +/- 0.05 V versus (vs.) the reversible hydrogen electrode (RHE), is achieved when the MoS2/WS2 heterojunction is introduced as a catalyst even without intentional generation of catalytic sites. As a result, the photocurrent of similar to 4.0 mA cm(-2) occurs even at 0 V vs. RHE. Furthermore, the beneficial effect of the atomically scaled vertical heterojunction is explained by the built-in potential resulted from efficient charge transfer in type-II heterojunctions with the support of first-principles calculations. Our demonstration not only offers an unprecedented approach to investigating the fundamental PEC characteristics in relation to the tailored properties of a catalyst but also proposes a new catalytic architecture, thereby enabling the design of highly efficient PEC systems. English ELSEVIER ACTIVE EDGE SITES CATALYTIC-ACTIVITY SULFUR VACANCIES MOS2 NANOSHEETS GENERATION GRAPHENE SURFACE PLANE Boosting the photocatalytic hydrogen evolution performance via an atomically thin 2D heterojunction visualized by scanning photoelectrochemical microscopy Article 10.1016/j.nanoen.2019.104053 1 NANO ENERGY, v.65 NANO ENERGY 65 scie scopus 000496445600018 2-s2.0-85072216562 Chemistry, Physical Nanoscience & Nanotechnology Materials Science, Multidisciplinary Physics, Applied Chemistry Science & Technology - Other Topics Materials Science Physics Article ACTIVE EDGE SITES CATALYTIC-ACTIVITY SULFUR VACANCIES MOS2 NANOSHEETS GENERATION GRAPHENE SURFACE PLANE Photoelectrochemical hydrogen evolution Transition metal dichalcogenides Heterojunction Catalyst Spatially resolved PEC characterization