High-Temperature Wetting and Dewetting Dynamics of Silver Droplets on Molybdenum Surfaces

Lin Lin; Chuan-Jiang Xu; Xiao-Dong Wang; Duu-Jong Lee

doi:10.1021/acs.langmuir.2c02884

High-Temperature Wetting and Dewetting Dynamics of Silver Droplets on Molybdenum Surfaces

Lin Lin, Chuan-Jiang Xu, Xiao-Dong Wang^*, Duu-Jong Lee^*

^*Corresponding author for this work

Department of Mechanical Engineering

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

6 Citations (Scopus)

Abstract

The wetting and dewetting behaviors of Ag droplets on Mo(100), Mo(110), and Mo(111) surfaces were investigated over 1200-2000 K via molecular dynamics simulations. We used the diffusion energy barriers of Ag droplets on the three surfaces to analyze the phenomenon of different precursor films and adsorption layers on the different surfaces. Alloying enabled the Mo(111) surface better wettability in both Mo(110) and Mo(111) surfaces, where there were significant precursor films. We observed that the dewetting rate was the fastest on the surface with the densest adsorption layer. Simulations proved that the same molecular kinetic theory model was applicable to not only the wetting process but also the dewetting process on the same surface. We also provided evidence to support the fact that an increased temperature could reduce the time to reach equilibrium for the wetting and dewetting processes.

Original language	English
Pages (from-to)	1135–1144
Journal	Langmuir
Volume	39
Issue number	3
Online published	9 Jan 2023
DOIs	https://doi.org/10.1021/acs.langmuir.2c02884
Publication status	Published - 24 Jan 2023

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title = "High-Temperature Wetting and Dewetting Dynamics of Silver Droplets on Molybdenum Surfaces",

abstract = "The wetting and dewetting behaviors of Ag droplets on Mo(100), Mo(110), and Mo(111) surfaces were investigated over 1200-2000 K via molecular dynamics simulations. We used the diffusion energy barriers of Ag droplets on the three surfaces to analyze the phenomenon of different precursor films and adsorption layers on the different surfaces. Alloying enabled the Mo(111) surface better wettability in both Mo(110) and Mo(111) surfaces, where there were significant precursor films. We observed that the dewetting rate was the fastest on the surface with the densest adsorption layer. Simulations proved that the same molecular kinetic theory model was applicable to not only the wetting process but also the dewetting process on the same surface. We also provided evidence to support the fact that an increased temperature could reduce the time to reach equilibrium for the wetting and dewetting processes.",

author = "Lin Lin and Chuan-Jiang Xu and Xiao-Dong Wang and Duu-Jong Lee",

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T1 - High-Temperature Wetting and Dewetting Dynamics of Silver Droplets on Molybdenum Surfaces

AU - Lin, Lin

AU - Xu, Chuan-Jiang

AU - Wang, Xiao-Dong

AU - Lee, Duu-Jong

PY - 2023/1/24

Y1 - 2023/1/24

N2 - The wetting and dewetting behaviors of Ag droplets on Mo(100), Mo(110), and Mo(111) surfaces were investigated over 1200-2000 K via molecular dynamics simulations. We used the diffusion energy barriers of Ag droplets on the three surfaces to analyze the phenomenon of different precursor films and adsorption layers on the different surfaces. Alloying enabled the Mo(111) surface better wettability in both Mo(110) and Mo(111) surfaces, where there were significant precursor films. We observed that the dewetting rate was the fastest on the surface with the densest adsorption layer. Simulations proved that the same molecular kinetic theory model was applicable to not only the wetting process but also the dewetting process on the same surface. We also provided evidence to support the fact that an increased temperature could reduce the time to reach equilibrium for the wetting and dewetting processes.

AB - The wetting and dewetting behaviors of Ag droplets on Mo(100), Mo(110), and Mo(111) surfaces were investigated over 1200-2000 K via molecular dynamics simulations. We used the diffusion energy barriers of Ag droplets on the three surfaces to analyze the phenomenon of different precursor films and adsorption layers on the different surfaces. Alloying enabled the Mo(111) surface better wettability in both Mo(110) and Mo(111) surfaces, where there were significant precursor films. We observed that the dewetting rate was the fastest on the surface with the densest adsorption layer. Simulations proved that the same molecular kinetic theory model was applicable to not only the wetting process but also the dewetting process on the same surface. We also provided evidence to support the fact that an increased temperature could reduce the time to reach equilibrium for the wetting and dewetting processes.

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DO - 10.1021/acs.langmuir.2c02884

M3 - RGC 21 - Publication in refereed journal

SN - 0743-7463

VL - 39

SP - 1135

EP - 1144

JO - Langmuir

JF - Langmuir

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ER -

High-Temperature Wetting and Dewetting Dynamics of Silver Droplets on Molybdenum Surfaces

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