Multi-pulses ablation threshold of Ni-based superalloy irradiated by ultrafast laser with different pulse duration

Yun Gao; Zenan Yang; Chengwei Song; Yuanhang Zhang; Jian Zhang; Qinghua Zhang; Mincai Liu; Yaguo Li

doi:10.11884/HPLPB202234.210341

[3] Bandyopadhyay S, Sundar J K S, Sundararajan G, et al. Geometrical features and metallurgical characteristics of Nd: YAG laser drilled holes in thick IN718 and Ti–6Al–4V sheets[J]. Journal of Materials Processing Technology, 127, 83-95(2002).

[5] Ancona A, Döring S, Jauregui C, et al. Femtosecond and picosecond laser drilling of metals at high repetition rates and average powers[J]. Optics Letters, 34, 3304-3306(2009).

[6] Zhang Wei, Cheng Guanghua, Feng Qiang, et al. Femtosecond laser machining characteristics in a single-crystal superalloy[J]. Rare Metals, 30, 639-642(2011).

[7] Kerse C, Kalaycıoğlu H, Elahi P, et al. Ablation-cooled material removal with ultrafast bursts of pulses[J]. Nature, 537, 84-88(2016).

[9] Petronić S, Milosavljević A, Radaković Z, et al. Analysis of geometrical characteristics of pulsed ND: YAG laser drilled holes in superalloy Nimonic 263 sheets[J]. Tehnički Vjesnik, 17, 61-66(2010).

[10] Das D K, Pollock T M. Femtosecond laser machining of cooling holes in thermal barrier coated CMSX4 superalloy[J]. Journal of Materials Processing Technology, 209, 5661-5668(2009).

[11] Weck A, Crawford T H R, Wilkinson D S, et al. Laser drilling of high aspect ratio holes in copper with femtosecond, picosecond and nanosecond pulses[J]. Applied Physics A, 90, 537-543(2008).

[12] Kirkwood S E, van Popta A C, Tsui Y Y, et al. Single and multiple shot near-infrared femtosecond laser pulse ablation thresholds of copper[J]. Applied Physics A, 81, 729-735(2005).

[13] Mannion P T, Magee J, Coyne E, et al. The effect of damage accumulation behaviour on ablation thresholds and damage morphology in ultrafast laser micro-machining of common metals in air[J]. Applied Surface Science, 233, 275-287(2004).

[14] Di Niso F, Gaudiuso C, Sibillano T, et al. Influence of the repetition rate and pulse duration on the incubation effect in multiple-shots ultrafast laser ablation of steel[J]. Physics Procedia, 41, 698-707(2013).

[15] Le Harzic R, Breitling D, Weikert M, et al. Ablation comparison with low and high energy densities for Cu and Al with ultra-short laser pulses[J]. Applied Physics A, 80, 1589-1593(2005).

[16] Feng Q, Picard Y N, Liu H, et al. Femtosecond laser micromachining of a single-crystal superalloy[J]. Scripta Materialia, 53, 511-516(2005).

[17] Semaltianos N G, Perrie W, French P, et al. Femtosecond laser ablation characteristics of nickel-based superalloy C263[J]. Applied Physics A, 94, 999-1009(2009).

[18] Semaltianos N G, Perrie W, Cheng J, et al. Picosecond laser ablation of nickel-based superalloy C263[J]. Applied Physics A, 98, 345-355(2010).

[19] Miotello A, Kelly R. Laser-induced phase explosion: new physical problems when a condensed phase approaches the thermodynamic critical temperature[J]. Applied Physics A, 69, S67-S73(1999).

[21] Byskov-Nielsen J, Savolainen J M, Christensen M S, et al. Ultra-short pulse laser ablation of metals: threshold fluence, incubation coefficient and ablation rates[J]. Applied Physics A, 101, 97-101(2010).

[24] Ni Xiaocheng, Wang C Y, Yang Li, et al. Parametric study on femtosecond laser pulse ablation of Au films[J]. Applied Surface Science, 253, 1616-1619(2006).

[26] Harilal S S, Diwakar P K, Hassanein A. Electron-ion relaxation time dependent signal enhancement in ultrafast double-pulse laser-induced breakdown spectroscopy[J]. Applied Physics Letters, 103, 041102(2013).