[1] Qibiao YANG, Hong ZHANG, Wei ZHOU et al. Surface incubation effect of carbide yg6 induced by femtosecond laser. Acta Photonica Sinica, 48, 614002(2019).

[2] Junzhan ZHANG, Yuanmin ZHANG, Yongsheng LIU et al. Femtosecond laser ablation properties of ZrO₂ and Al₂O₃ ceramics at linear and circular polarized light. Acta Photonica Sinica, 47, 614003(2018).

[3] Shi SU, Zhiyong AN, Wei LIANG et al. Comparisons and analysis of drilling experiment using different pulse laser wavaforms. Acta Photonica Sinica, 41, 565-570(2012).

[4] Fei CHANG, Jian ZHANG, Yunchao XIE et al. Fabrication， characterization， and photocatalytic performance of exfoliated g-C3N4-TiO2 hybrids. Applied Surface Science, 311, 574-581(2014).

[5] Xiangdong GAO, Yanxi ZHANG. Monitoring of welding status by molten pool morphology during high-power disk laser welding. Optik-International Journal for Light and Electron Optics, 126, 1797-1802(2015).

[6] A HEIDER, J SOLLINGER et al. High-speed X-ray analysis of spatter formation in laser welding of copper. Physics Procedia, 41, 112-118(2013).

[7] Y OKAMOTO, H YAMAMOTO, A OKADA et al. Velocity and angle of spatter in fine laser processing. Physics Procedia, 39, 792-799(2012).

[8] Yu GAN, Wenxian WANG, Zeqin CUI et al. Numerical and experimental study of the temperature field evolution. Optik-International Journal for Light and Electron Optics, 126, 739-743(2015).

[9] M J ZHANG, G Y CHEN, Y ZHOU et al. Observation of spatter formation mechanisms in high-power fiber laser welding of thick plate. Applied Surface Science, 280, 868-875(2013).

[10] M SIMONELLI, C TUCK, N T ABOULKHAIR et al. A study on the laser spatter and the oxidation reactions during selective laser melting of 316l stainless steel， Al-Si₁₀-Mg， and Ti-6Al-4V. Metallurgical and Materials Transactions A-Physical Metallurgy and Materials Science, 46, 3842-3851(2015).

[11] Xinmiao XIA, Zhaoliang JIANG, Pengfei XU. A detection algorithm of spatter on welding plate surface based on machine vision. Optoelectronics Letters, 15, 52-56(2019).

[12] P Y SHCHEGLOV, A V GUMENYUK, I B GORNUSHKIN et al. Vapor–plasma plume investigation during high-power fiber laser welding. Laser Physics, 23, 16001(2012).

[13] Huang WEI, K RADOVAN. A laser-based vision system for weld quality inspection. Sensors, 11, 506-521(2011).

[14] Kai LI, Hongming GAO, Haichao LI et al. Droplet rebounded spatter in dry hyperbaric gas metal arc welding process. International Journal of Advanced Manufacturing Technology, 74, 693-698(2014).

[15] P Y SHCHEGLOV, S A USPENSKIY, AV GUMENYUK et al. Plume attenuation of laser radiation during high power fiber laser welding. Laser Physics Letters, 8, 475-480(2011).

[16] D COLOMBO, B M COLOSIMO, B PREVITALI. Comparison of methods for data analysis in the remote monitoring of remote laser welding. Optics & Lasers in Engineering, 51, 34-46(2013).

[17] Bin CAO, Yuanpeng XIANG, Xiaoqing LV et al. Approximate entropy-a new statistic to quantify arc and welding process stability in short-circuiting gas metal arc welding. Chinese Physics B, 17, 865-879(2008).

[18] J POWELL, A F H KAPLAN. Spatter in laser welding. Journal of Laser Applications, 23, 1-7(2011).

[19] M SCHWEIER, J F HEINS, M W HAUBOLD et al. spatter formation in laser welding with beam oscillation. Physics Procedia, 41, 20-30(2013).

[20] Ye HUANG, Xueming HUA, Fang LI et al. Spatter feature analysis in laser welding based on motion tracking method. Journal of Manufacturing Processes, 55, 220-229(2020).

[21] A K PULHANI, B M SURI et al. Time-resolved emission spectroscopic study of laser-induced steel plasmas. Plasma Science and Technology, 15, 546(2013).

[22] Xiangdong GAO, Yan SUN, S KATAYAMA. Neural network of plume and spatter for monitoring high-power disk laser welding. International Journal of Precision Engineering and Manufacturing-Green technology, 1, 293-298(2014).

[23] Guanfu LONG. Analysis of characteristics of spatters during high-power disk laser welding(2012).