Progress in Strongly Coupled Laser Thermal-Mechanical Damage Effects

WANG Ruixing; YUAN Wu; MA Te; QIU Cheng; DU Wenqi; ZHANG Tianyi; WANG Gaojie; SONG Hongwei; HUANG Chenguang

doi:10.6052/1000-0992-25-042

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Article Navigation > Advances in Mechanics > 2026 > Accepted Manuscript

Wang R X, Yuan W, Ma T, Qiu C, Du W Q, Zhang T Y, Wang G J, Song H W, Huang C G. Progress in Strongly Coupled Laser Thermal-Mechanical Damage Effects. Advances in Mechanics, in press doi: 10.6052/1000-0992-25-042

Citation:

Wang R X, Yuan W, Ma T, Qiu C, Du W Q, Zhang T Y, Wang G J, Song H W, Huang C G. Progress in Strongly Coupled Laser Thermal-Mechanical Damage Effects. Advances in Mechanics, in press doi: 10.6052/1000-0992-25-042

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Progress in Strongly Coupled Laser Thermal-Mechanical Damage Effects

doi: 10.6052/1000-0992-25-042 cstr: 32046.14.1000-0992-25-042

WANG Ruixing^{1, 2
,},
YUAN Wu^{1, 2},
MA Te^{1, 2},
QIU Cheng^{1, 2},
DU Wenqi^{1, 2},
ZHANG Tianyi^{1, 2},
WANG Gaojie^{1, 2},
SONG Hongwei^{1, 2
,
,},
HUANG Chenguang²

1.
Institute of Mechanics, Chinese Academy of Sciences, Beijing 100190, China
2.
School of Engineering Science, University of Chinese Academy of Sciences, Beijing 100049, China

More Information

Corresponding author: songhw@imech.ac.cn
Received Date: 2014-01-02
Accepted Date: 2014-03-04

Available Online: 2014-05-06

Abstract

Abstract

With the rapid advancement of high-energy laser technology, the application scenarios of laser-induced damage effects are expanding to higher-speed engineering structures. The coupling effects among high-energy lasers, high-speed airflow environments, and materials or structures become significantly stronger, thereby markedly influencing the thermal and mechanical damage behaviors of lasers and even inducing novel damage mechanisms and failure phenomena. Furthermore, issues such as thermo-mechanical coupling resulting from laser irradiation and the thermo-mechanical-impact-ablation coupling under combined loading of different laser systems further complicate the coupling behaviors of damage effects. Research on strongly coupled laser-induced thermo-mechanical damage effects addresses the latest developmental needs in related fields, involving interdisciplinary integration of optics, heat transfer, materials science, solid mechanics, and fluid mechanics. It constitutes a fundamental scientific challenge common to high-tech domains such as laser weapon effect evaluation, advanced laser manufacturing, and spacecraft protection. This paper systematically reviews recent research progress by domestic and international scholars in this field. It summarizes findings from several key aspects: novel phenomena and mechanisms of laser-induced thermo-mechanical damage under strong coupling conditions, multi-scale thermo-mechanical ablation mechanisms and models of laser-irradiated composite materials, similarity criteria for laser-induced thermo-mechanical damage under complex loads and environments, multi-field coupled numerical simulation methods, ground simulation testing techniques and in-situ multi-field measurement technologies, laser protection and reinforcement strategies, and laser-based intelligent sensing and damage assessment. Finally, based on current trends, future research directions in this field are prospected. This paper aims to provide theoretical foundations and technical references for both mechanistic studies and engineering applications of strongly coupled laser-induced thermo-mechanical damage effects.
- Strong coupling,
- Laser damage effect,
- Multi-field coupled numerical simulation,
- Experimental testing,
- Laser protection,
- Intelligent laser

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References(214)

References

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