[1] Chern T S, Tsai H L. Wetting and sealing of interface between 7056 Glass and Kovar alloy[J]. Materials Chemistry and Physics, 104, 472-478(2007).

[2] Malfait W J, Klemenčič R, Lang B et al. Optimized solder alloy for glass-to-metal joints by simultaneous soldering and anodic bonding[J]. Journal of Materials Processing Technology, 236, 176-182(2016).

[3] Oberhammer J, Niklaus F, Stemme G. Sealing of adhesive bonded devices on wafer level[J]. Sensors and Actuators A: Physical, 110, 407-412(2004).

[4] Sugiyama S, Kiuchi M, Yanagimoto J. Application of semisolid joining: part 4 glass/metal, plastic/metal, or wood/metal joining[J]. Journal of Materials Processing Technology, 201, 623-628(2008).

[5] Utsumi A, Ooie T, Yano T et al. Direct bonding of glass and metal using short pulsed laser[J]. Journal of Laser Micro/Nanoengineering, 2, 133-136(2007).

[6] Ozeki Y, Inoue T, Tamaki T et al. Direct welding between copper and glass substrates with femtosecond laser pulses[J]. Applied Physics Express, 1, 082601(2008).

[7] Zhang G D, Cheng G H. Direct welding of glass and metal by 1 kHz femtosecond laser pulses[J]. Applied Optics, 54, 8957-8961(2015).

[8] Carter R M, Troughton M, Chen J Y et al. Picosecond laser bonding of highly dissimilar materials[J]. Proceedings of SPIE, 9992, 999207(2016).

[9] Ciuca O P, Carter R M, Prangnell P B et al. Characterisation of weld zone reactions in dissimilar glass-to-aluminium pulsed picosecond laser welds[J]. Materials Characterization, 120, 53-62(2016).

[10] Carter R M, Troughton M, Chen J Y et al. Towards industrial ultrafast laser microwelding: SiO2 and BK7 to aluminum alloy[J]. Applied Optics, 56, 4873-4881(2017).

[11] Li P, Xu X W, Tan W S et al. Improvement of laser transmission welding of glass with titanium alloy by laser surface treatment[J]. Materials, 11, 2060(2018).

[12] Zhang M, Chen C J, Zou T et al. Study on tensile strength and mechanism of glass-to-kovar alloy with laser welding[J]. Applied Laser, 36, 421-427(2016).

[13] Zhang G D, Stoian R, Zhao W et al. Femtosecond laser Bessel beam welding of transparent to non-transparent materials with large focal-position tolerant zone[J]. Optics Express, 26, 917-926(2018).

[14] Wu H, Zhang N, He M et al. Calculation of argon-aluminum interatomic potential and its application in molecular dynamics simulation of femtosecond laser ablation[J]. Chinese Journal of Lasers, 43, 0802004(2016).

[15] Cheng C, Wu A Q, Xu X. Molecular dynamics simulation of ultrafast laser ablation of fused silica[J]. Journal of Physics: Conference Series, 59, 100-104(2007).

[16] Chen B, Zhu W H, Chen P et al. Mechanism of femtosecond laser ablating CuZr amorphous alloy[J]. Laser＆Optoelectronics Progress, 52, 041406(2015).

[17] Karim E T, Shugaev M, Wu C P et al. Atomistic simulation study of short pulse laser interactions with a metal target under conditions of spatial confinement by a transparent overlayer[J]. Journal of Applied Physics, 115, 183501(2014).

[18] Karim E T, Shugaev M V, Wu C P et al. Experimental characterization and atomistic modeling of interfacial void formation and detachment in short pulse laser processing of metal surfaces covered by solid transparent overlayers[J]. Applied Physics A, 122, 407(2016).

[19] Sun S Z, Jin C S, Yu B et al. Reflection and resputtering of Mo/Si atoms during high-energy deposition[J]. Acta Optica Sinica, 40, 1102001(2020).

[20] Wu X F, Mei S L. Research progress in femtosecond laser machining mechanism and simulation analysis[J]. Laser & Optoelectronics Progress, 58, 1900005(2021).

[21] Hou C J, Wang G W, Wang Y et al. Molecular dynamics simulation of laser melting of sliver nanoparticles on SiO2 substrate[J]. Chinese Journal of Lasers, 48, 0802025(2021).

[22] Zhou Y, Hu Y X. Two temperature model coupling with molecular dynamics simulation of femtosecond laser inducing nickel nano-droplet[J]. Electromachining & Mould, 45-50(2022).

[23] Niu Z W, Li L, Guan Y. Molecular dynamics simulation of the femtosecond laser melting of Au nanoparticles[J]. Journal of University of Shanghai for Science and Technology, 41, 103-107, 148(2019).

[24] Plimpton S. Fast parallel algorithms for short-range molecular dynamics[J]. Journal of Computational Physics, 117, 1-19(1995).

[25] Lennard-Jones J E. Cohesion[J]. Proceedings of the Physical Society, 43, 461-482(1931).

[27] de Coninck J, Blake T. Wetting and molecular dynamics simulations of simple liquids[J]. Annual Review of Materials Research, 38, 1-22(2008).

[28] Campbell C T. Ultrathin metal films and particles on oxide surfaces: structural, electronic and chemisorptive properties[J]. Surface Science Reports, 27, 1-111(1997).

[29] Sangiorgi R, Muolo M L, Chatain D et al. Wettability and work of adhesion of nonreactive liquid metals on silica[J]. Journal of the American Ceramic Society, 71, 742-748(1988).

[30] Zhakhovskii V V, Inogamov N A, Petrov Y V et al. Molecular dynamics simulation of femtosecond ablation and spallation with different interatomic potentials[J]. Applied Surface Science, 255, 9592-9596(2009).

[31] Shugaev M V, Wu C P, Armbruster O et al. Fundamentals of ultrafast laser-material interaction[J]. MRS Bulletin, 41, 960-968(2016).

[32] Rutherford A M, Duffy D M. The effect of electron-ion interactions on radiation damage simulations[J]. Journal of Physics: Condensed Matter, 19, 496201(2007).

[33] Humphrey W, Dalke A, Schulten K. VMD: visual molecular dynamics[J]. Journal of Molecular Graphics, 14, 33-38(1996).

[34] Starikov S V, Pisarev V V. Atomistic simulation of laser-pulse surface modification: predictions of models with various length and time scales[J]. Journal of Applied Physics, 117, 135901(2015).