[1] Buchner S P, Miller F, Pouget V, et al. Pulsed-laser testing for single-event effects investigations[J]. IEEE Transactions on Nuclear Science, 60, 1852-1875(2013).

[2] Hales J M, Khachatrian A, Buchner S, et al. New approach for pulsed-laser testing that mimics heavy-ion charge deposition profiles[J]. IEEE Transactions on Nuclear Science, 67, 81-90(2020).

[3] Hales J M, Khachatrian A, Buchner S, et al. Mapping the spatial dependence of charge-collection efficiency in semiconductor devices using pulsed-laser testing[J]. IEEE Transactions on Nuclear Science, 68, 617-625(2021).

[4] Hales J M, Khachatrian A, Ildefonso A, et al. Pulsed-laser testing to quantitatively evaluate latchup sensitivity in mixed-signal ASICs[J]. IEEE Transactions on Nuclear Science, 69, 429-435(2022).

[5] Habing D H. The use of lasers to simulate radiation-induced transients in semiconductor devices and circuits[J]. IEEE Transactions on Nuclear Science, 12, 91-100(1965).

[6] Buchner S P, Wilson D, Kang K, et al. Laser simulation of single event upsets[J]. IEEE Transactions on Nuclear Science, 34, 1227-1233(1987).

[7] Richter A K, Arimura I. Simulation of heavy charged particle tracks using focused laser beams[J]. IEEE Transactions on Nuclear Science, 34, 1234-1239(1987).

[8] Hales J M, Khachatrian A, Buchner S, et al. Using twophoton absption pulsedlaser excitation to simulate radiation effects in microelectronics[C]Proceedings of 2018 Conference on Lasers ElectroOptics. 2018.

[9] Ildefonso A, Fleetwood Z E, Tzintzarov G N, et al. Optimizing optical parameters to facilitate correlation of laser- and heavy-ion-induced single-event transients in SiGe HBTs[J]. IEEE Transactions on Nuclear Science, 66, 359-367(2019).

[10] Hales J M, Khachatrian A, Roche N J H, et al. Simulation of laser-based two-photon absorption induced charge carrier generation in silicon[J]. IEEE Transactions on Nuclear Science, 62, 1550-1557(2015).

[11] Shangguan Shipeng, Ma Yingqi, Han Jianwei, et al. Single event effects of SiC diode demonstrated by pulsed-laser two photon absorption[J]. Microelectronics Reliability, 125, 114364(2021).

[12] Han Jianwei, Shangguan Shipeng, Ma Yingqi, . Research progress for single event effects of space payloads by pulsed laser simulation[J]. Journal of Deep Space Exploration, 4, 577-584(2017).

[13] Hu Xiwei. Fundamentals of plasma they[M]. Beijing: Peking University Press, 2006

[14] Green M A. Self-consistent optical parameters of intrinsic silicon at 300 K including temperature coefficients[J]. Solar Energy Materials and Solar Cells, 92, 1305-1310(2008).

[15] Huang Jianguo, Han Jianwei. Calculation of LET in SEE simulation by pulsed laser[J]. Science in China (Series G), 48, 113-121(2005).

[16] Liu Enke, Zhu Bingsheng, Luo Jinsheng. The physics of semiconducts[M]. 7th ed. Beijing: Publishing House of Electronics Industry, 2011

[17] Batani D, Joachain C J, Martellucci S. Atoms plasmas in superintense laser fields[M]. Bologna: Società Italiana di Fisica, 2004.

[18] Wang Zhuqin, Lan Sheng. Electrical conductivity simulation of plasma based on local thermodynamic equilibrium[J]. Journal of Atomic and Molecular Physics, 32, 259-263(2015).

[19] Guan Ming, Guo Hongxia, Chen Zhehao, . Physical process simulation of single event effect[J]. Modern Applied Physics, 10, 030602(2019).

[20] Chettah A, Kucal H, Wang Z G, et al. Behavior of crystalline silicon under huge electronic excitations: a transient thermal spike description[J]. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 267, 2719-2724(2009).

[21] Lazanu I, Lazanu S. Contribution of the electron-phonon interaction to Lindhard energy partition at low energy in Ge and Si detectors for astroparticle physics applications[J]. Astroparticle Physics, 75, 44-54(2016).

[22] Hou Mingdong, Zhen Honglou, Zhang Qingxiang, . Single event effects induced by heavy ion in semiconductor device[J]. Nuclear Physics Review, 17, 165-170(2000).