[Oral Presentation]In situ probing of electron transfer at the dynamic MoS2/Graphene-water interface for modulating boundary slip

In situ probing of electron transfer at the dynamic MoS2/Graphene-water interface for modulating boundary slip
ID:6 Submission ID:5 View Protection:ATTENDEE Updated Time:2024-10-13 21:45:38 Hits:189 Oral Presentation

Start Time:2024-10-19 11:20 (Asia/Shanghai)

Duration:15min

Session:[S3] Nano-materials and Nano-coatings » [S3A] Session 3A

No files

Abstract
The boundary slip condition is pivotal for nanoscale fluid motion. Recent research has primarily focused on simulating the interaction mechanism between the electronic structure of two-dimensional materials and slip of water at the nanoscale, raising the possibility for ultralow friction flow of water at the nanoscale. However, experimentally elucidating electronic interactions at the dynamic solid-liquid interface to control boundary slip poses a significant challenge. In this study, the crucial role of electron structures at the dynamic solid-liquid interface in regulating slip length was revealed. Notably, the slip length of water on the molybdenum disulfide/graphene (MoS2/G) heterostructure (100.9 ± 3.6 nm) significantly exceeded that of either graphene (27.7 ± 2.2 nm) or MoS2 (5.7 ± 3.1 nm) alone. It was also analyzed how electron transfer significantly affected interface interactions. Excess electrons played a crucial role in determining the type and proportion of excitons at both MoS2-water and MoS2/G-water interfaces. Additionally, by applying voltage, distinct photoluminescence (PL) responses at static and dynamic interfaces were discovered, achieving a 5-fold modulation in PL intensity and a 2-fold modulation in the trion to exciton intensity ratio. More electrons transfer from the top graphene to the bottom MoS2 at the MoS2/G-water interface, reducing surface charge density. Thus, the reduction of electrostatic interactions between the solid and water leads to an increased slip length of water on the MoS2/G heterostructure. The process aids in comprehending the origin of frictional resistance at the subatomic scale. This work establishes a foundation for actively controlling and designing of fluid transport at the nanoscale.
Keywords
solid-liquid interface;slip length;electron transfer;Two-Dimensional Materials
Speaker
Yishu Han
Tsinghua University, China

Submission Author
大猛 刘 清华大学
逸姝 韩 清华大学
Comment submit
Verification code Change another
All comments
Mr. Duan Jindi,       Tel. 13971036507  

Mr. Jiang Chao,        Tel. 18971299299

E-mail:icse2024@126.com
Dr. Liu Mingming,  Tel. 19862516876

E-mail:mmliu@sdut.edu.cn

Dr. Zhu Jian,         Tel. 15810878528 E-mail: zhujian@sdut.edu.cn
Dr. Zhang Xiuli,     Tel. 15064351998

E-mail: zhangxiulli@163.com

Prof. Guo Qianjian,   Tel. 13969397001

Registration Submission