scholarly journals The study of water wettability on solid surfaces by molecular dynamics simulation

2021 ◽  
pp. 121916
Author(s):  
Yinhao Yu ◽  
Xiongwen Xu ◽  
Jinping Liu ◽  
Yuehui Liu ◽  
Wenhao Cai ◽  
...  
Keyword(s):  
Molecular Dynamics ◽  
Molecular Dynamics Simulation ◽  
Solid Surfaces ◽  
Dynamics Simulation ◽  
Water Wettability

MOLECULAR DYNAMICS SIMULATION OF PULSED LASER ABLATION

2011 ◽  
Vol 25 (04) ◽  
pp. 543-550 ◽  
Author(s):  
XIU-FANG GONG ◽  
GONG-XIAN YANG ◽  
PENG LI ◽  
YIN WANG ◽  
XI-JING NING
Keyword(s):  
Molecular Dynamics ◽  
Molecular Dynamics Simulation ◽  
Pulsed Laser ◽  
Pulsed Laser Ablation ◽  
Laser Pulses ◽  
Solid Surfaces ◽  
Dynamics Simulation ◽  
Angular Distributions ◽  
Adiabatic Expansion ◽  
Expansion Model

We have developed a simplified molecular-dynamical model for simulating ablation of solid surfaces by laser pulses, and specifically investigated expansion of Cu cloud in vacuum vaporized on the surface, showing that the angular distributions of the plume depend on the shape of the laser spot on the surface. In particular, experimentally observed flipover effects have been obtained, and an adiabatic constant determined from our simulations via an adiabatic expansion model agrees well with previous measurements.

scholarly journals Movement pattern of an ellipsoidal nanoparticle confined between solid surfaces: Theoretical model and molecular dynamics simulation

Friction ◽  
2020 ◽  
Author(s):  
Junqin Shi ◽  
Xiangzheng Zhu ◽  
Kun Sun ◽  
Liang Fang
Keyword(s):  
Molecular Dynamics ◽  
Theoretical Model ◽  
Molecular Dynamics Simulation ◽  
Movement Pattern ◽  
Axial Ratio ◽  
Surface Damage ◽  
Solid Surfaces ◽  
Dynamics Simulation ◽  
Copper Surfaces ◽  
Good Agreement

Abstract The movement pattern of ellipsoidal nanoparticles confined between copper surfaces was examined using a theoretical model and molecular dynamics simulation. Initially, we developed a theoretical model of movement patterns for hard ellipsoidal nanoparticles. Subsequently, the simulation indicated that there are critical values for increasing the axial ratio, driving velocity of the contact surface, and lowering normal loads (i.e., 0.83, 15 m/s, and 100 nN under the respective conditions), which in turn change the movement pattern of nanoparticles from sliding to rolling. Based on the comparison between the ratio of arm of force (e/h) and coefficient of friction (μ) the theoretical model was in good agreement with the simulations and accurately predicted the movement pattern of ellipsoidal nanoparticles. The sliding of the ellipsoidal nanoparticles led to severe surface damage. However, rolling separated the contact surfaces and thereby reduced friction and wear.

Heat Capacity of Nanoconfined Liquid: A Molecular Dynamics Simulation

2017 ◽  
Author(s):  
Rifat Mahmud ◽  
A. K. M. Monjur Morshed ◽  
Titan C. Paul
Keyword(s):  
Molecular Dynamics ◽  
Heat Capacity ◽  
Molecular Dynamics Simulation ◽  
Molar Heat Capacity ◽  
Molecular Model ◽  
Solid Surfaces ◽  
Dynamics Simulation ◽  
Bulk Liquid ◽  
Liquid Domain ◽  
Lennard Jones

Equilibrium molecular dynamics (EMD) simulations aiming to investigate the effect of confinement gap thickness on constant volume molar heat capacity (Cv) of the confined liquid in nanoscale have been carried out by simultaneously controlling the density and temperature of the liquid domain. Simplified Lennard-Jones (LJ) molecular model is used to model the system where the liquid is entrapped between two flat solid surfaces separated by a distance varying from 0.585 nm to 27.8 nm. Molar heat capacity of the bulk liquid has been evaluated using fluctuation formula which matches greatly with the NIST data and published literatures. But in case of confined liquid, molar heat capacity is observed to vary significantly with the gap thickness. For a specific range of gap thickness, molar heat capacity of the confined liquid is found higher than that of the bulk. But molar heat capacity of the nanogap confined liquid becomes independent of the gap thickness and approaches to that of the bulk liquid as gap thickness is greater than this specific range (6.14 nm for 100 K temperature of the confined liquid).

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