A multiscale study of film thickness dependent femtosecond laser spallation and ablation

Pengfei Ji; Yuwen Zhang; Yiming Rong; Yong Tang

doi:10.1615/ihtc16.nmt.021385

A multiscale study of film thickness dependent femtosecond laser spallation and ablation

Pengfei Ji
, Yuwen Zhang
, Yiming Rong
, Yong Tang

Southern University of Science and Technology
University of Missouri
South China University of Technology

Research output: Contribution to journal › Conference article › peer-review

Abstract

A multiscale studying integrating ab initio quantum mechanics, classical molecular dynamics and two-temperature model, is carried out to study film thickness dependent femtosecond laser spallation and ablation. As an interval of 130.73 , five silver films with increasing thickness from 392.19 to 915. 11 are simulated. Absorbed laser fluences of 0.1 / and 0.3 / are chosen to observe the laser spallation and ablation. The simulation results show that film thickness has close correlation with the Kelvin degree of heating of the laser irradiated silver films, which further affects femtosecond laser spallation and ablation. Suggestions for precise micromachining are proposed in this paper.

Original language	English
Pages (from-to)	7117-7124
Number of pages	8
Journal	International Heat Transfer Conference
Volume	2018-August
DOIs	https://doi.org/10.1615/ihtc16.nmt.021385
State	Published - 2018
Externally published	Yes
Event	16th International Heat Transfer Conference, IHTC 2018 - Beijing, China Duration: 10 Aug 2018 → 15 Aug 2018

Keywords

Materials processing
Multiscale modeling
Numerical simulation
Thermophysics and thermophysical properties

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10.1615/ihtc16.nmt.021385

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title = "A multiscale study of film thickness dependent femtosecond laser spallation and ablation",

abstract = "A multiscale studying integrating ab initio quantum mechanics, classical molecular dynamics and two-temperature model, is carried out to study film thickness dependent femtosecond laser spallation and ablation. As an interval of 130.73 , five silver films with increasing thickness from 392.19 to 915. 11 are simulated. Absorbed laser fluences of 0.1 / and 0.3 / are chosen to observe the laser spallation and ablation. The simulation results show that film thickness has close correlation with the Kelvin degree of heating of the laser irradiated silver films, which further affects femtosecond laser spallation and ablation. Suggestions for precise micromachining are proposed in this paper.",

keywords = "Materials processing, Multiscale modeling, Numerical simulation, Thermophysics and thermophysical properties",

author = "Pengfei Ji and Yuwen Zhang and Yiming Rong and Yong Tang",

note = "Publisher Copyright: {\textcopyright} 2018 International Heat Transfer Conference. All rights reserved.; 16th International Heat Transfer Conference, IHTC 2018 ; Conference date: 10-08-2018 Through 15-08-2018",

year = "2018",

doi = "10.1615/ihtc16.nmt.021385",

language = "英语",

volume = "2018-August",

pages = "7117--7124",

journal = "International Heat Transfer Conference",

issn = "2377-424X",

publisher = "Begell House Inc.",

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TY - JOUR

T1 - A multiscale study of film thickness dependent femtosecond laser spallation and ablation

AU - Ji, Pengfei

AU - Zhang, Yuwen

AU - Rong, Yiming

AU - Tang, Yong

PY - 2018

Y1 - 2018

N2 - A multiscale studying integrating ab initio quantum mechanics, classical molecular dynamics and two-temperature model, is carried out to study film thickness dependent femtosecond laser spallation and ablation. As an interval of 130.73 , five silver films with increasing thickness from 392.19 to 915. 11 are simulated. Absorbed laser fluences of 0.1 / and 0.3 / are chosen to observe the laser spallation and ablation. The simulation results show that film thickness has close correlation with the Kelvin degree of heating of the laser irradiated silver films, which further affects femtosecond laser spallation and ablation. Suggestions for precise micromachining are proposed in this paper.

AB - A multiscale studying integrating ab initio quantum mechanics, classical molecular dynamics and two-temperature model, is carried out to study film thickness dependent femtosecond laser spallation and ablation. As an interval of 130.73 , five silver films with increasing thickness from 392.19 to 915. 11 are simulated. Absorbed laser fluences of 0.1 / and 0.3 / are chosen to observe the laser spallation and ablation. The simulation results show that film thickness has close correlation with the Kelvin degree of heating of the laser irradiated silver films, which further affects femtosecond laser spallation and ablation. Suggestions for precise micromachining are proposed in this paper.

KW - Materials processing

KW - Multiscale modeling

KW - Numerical simulation

KW - Thermophysics and thermophysical properties

UR - https://www.scopus.com/pages/publications/85068319822

U2 - 10.1615/ihtc16.nmt.021385

DO - 10.1615/ihtc16.nmt.021385

M3 - 会议文章

AN - SCOPUS:85068319822

SN - 2377-424X

VL - 2018-August

SP - 7117

EP - 7124

JO - International Heat Transfer Conference

JF - International Heat Transfer Conference

T2 - 16th International Heat Transfer Conference, IHTC 2018

Y2 - 10 August 2018 through 15 August 2018

ER -

A multiscale study of film thickness dependent femtosecond laser spallation and ablation

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