[1] Liu X Y, Kang X M, He W G et al. Key technologies and prospect of ionic liquid electrospray thruster[J]. Journal of Astronautics, 40, 977-986(2019).

[2] Demmons N R, Lamarre N, Ziemer J K et al. Electrospray thruster propellant feed system for a gravity wave observatory mission[C], 4739(2016).

[3] Yu D R, Niu X, Wang T B et al. The developments of micro propulsion technology based on space gravitational wave detection task[J]. Acta Scientiarum Naturalium Universitatis Sunyatseni, 60, 194-212(2021).

[4] Fan Y P, Xia G Q, Han Y J et al. Research progress of ionic liquid micropropulsion technology[J]. Journal of Aerospace Power, 35, 1275-1285(2020).

[5] Liu X Y, He W G, Kang X M et al. Fabrication of porous emitters for ionic liquid ion source by wire electrical discharge machining combined with electrochemical etching[J]. The Review of Scientific Instruments, 90, 123304(2019).

[6] Courtney D G, Li H Q, Lozano P C. Electrochemical micromachining on porous nickel for arrays of electrospray ion emitters[J]. Journal of Microelectromechanical Systems, 22, 471-482(2013).

[7] Brikner N, Lozano P C. The role of upstream distal electrodes in mitigating electrochemical degradation of ionic liquid ion sources[J]. Applied Physics Letters, 101, 193504(2012).

[8] Natisin M R, Zamora H L, McGehee W A et al. Fabrication and characterization of a fully conventionally machined, high-performance porous-media electrospray thruster[J]. Journal of Micromechanics and Microengineering, 30, 115021(2020).

[9] Coffman C, Perna L, Li H Q et al. On the manufacturing and emission characteristics of a novel borosilicate electrospray source[C], 4035(2013).

[10] Yang Y T, Guo D W, Li X K et al. Development and characterization of a novel porous-media borosilicate glass ion sources for electrospray thruster[J]. Aerospace, 8, 297(2021).

[11] Ma C Y, Bull T, Ryan C N. Plume composition measurements of a high-emission-density electrospray thruster[J]. Journal of Propulsion and Power, 37, 816-831(2021).

[12] Zeng F Y, Zhou G F, Wang Y et al. Experimental study on femtosecond laser cutting quartz devices with complex shapes[J]. Laser & Optoelectronics Progress, 60, 0714002(2023).

[13] Xu S Z, Yao C Z, Dou H Q et al. An investigation on 800 nm femtosecond laser ablation of K9 glass in air and vacuum[J]. Applied Surface Science, 406, 91-98(2017).

[14] Machado L M, Samad R E, Freitas A Z et al. Microchannels direct machining using the femtosecond smooth ablation method[J]. Physics Procedia, 12, 67-75(2011).

[15] Yu X H, Qi D F, Zhou W J et al. Fabrication of periodic nanostructures on the surface of chalcogenide glass using ultrafast laser[J]. Laser & Optoelectronics Progress, 59, 1516019(2022).

[16] Couairon A, Mysyrowicz A. Femtosecond filamentation in transparent media[J]. Physics Reports, 441, 47-189(2007).

[17] Sakakura M, Shimotsuma Y, Miura K. Observation of stress wave and thermal stress in ultrashort pulse laser bulk processing inside glass[J]. Journal of Laser Micro, 12, 159-164(2017).

[18] Hu H F, Wang X L, Zhang N et al. Shock induced phenomena in high fluence femtosecond laser ablation of silica glass[J]. Proceedings of SPIE, 7843, 78430U(2010).

[19] Jiang X Y, Wang F F, Zhou W et al. Ultrafast dynamics in the interaction between femtosecond laser and materials[J]. Chinese Journal of Lasers, 49, 2200001(2022).

[20] Chen Y, Niu B. Femtosecond laser fabrication of porous ceramics for electrospray thruster emitter[J]. Proceedings of SPIE, 11885, 118850E(2021).

[21] Courtney D, Dandavino S, Shea H. Performance and applications of ionic electrospray micro-propulsion prototypes[C], 4672(2015).