[1] WEI Juncheng. Research on anti-radiation reinforcement technology for electronic system of remote sensing satellite camera[D](2019).

[2] WANG Li, GUO Shuling, XU Najun et al[M]. Introduction to satellite anti-radiation reinforcement technology(2021).

[3] SHEN Yuan. Study on total dose radiation effect of SOI NMOS devices[D](2012).

[4] CHEN Faguo, YU Weiyue, LIANG Runcheng et al. Development of extendable on-line test system for total ionizing dose effect of microprocessor[J]. Nuclear Techniques, 45, 110404(2022).

[5] WANG Dexin, ZHANG Suyalatu, HU Xinrong et al. Light output of EJ299-33A scintillator and its application[J]. Nuclear Techniques, 45, 020403(2022).

[6] LI Yan, WANG Chuan, LIU Liye et al. Development and performance calibration of position sensitive detector based on LaBr3(Ce) crystal coupled with SiPM[J]. Nuclear Techniques, 45, 070401(2022).

[7] YANG Song, ZHANG Xiaoquan, DENG Changming et al. Design of portable multi-function radiation detection system[J]. Nuclear Techniques, 45, 110403(2022).

[8] TANG Junjie, WANG Tuo, ZHANG Qiang et al. Characteristics of 6LiF/ZnS(Ag) scintillator used in position-sensitive neutron detectors[J]. Chinese Journal of Luminescence, 34, 78-81(2013).

[9] Grozdanov D N, Fedorov N A, Kopatch Y N et al. Semi-empirical gamma-ray response function of BGO, NaI(Tl) and LaBr3(Ce) scintillation detectors[J]. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 1014, 165741(2021).

[10] Shirakawa Y. Developments of directional detectors with NaI(Tl)/BGO scintillators[J]. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions With Materials and Atoms, 213, 255-259(2004).

[11] Lohrabian V, Kamali-Asl A, Harvani H G et al. Comparison of the X-ray tube spectrum measurement using BGO, NaI, LYSO, and HPGe detectors in a preclinical mini-CT scanner: Monte Carlo simulation and practical experiment[J]. Radiation Physics and Chemistry, 189, 109666(2021).

[12] Birowosuto M D, Dorenbos P, Krämer K W et al. Ce3+ activated LaBr3–xIx: high-light-yield and fast-response mixed halide scintillators[J]. Journal of Applied Physics, 103, 195(2008).

[13] CHEN Zhiqiang, CHEN Jingjing, SHU Shuangbao et al. Simulation study on the factors affecting the detection efficiency of a LaBr3(Ce) detector[J]. Nuclear Techniques, 45, 010401(2022).

[14] Meng Z, Chen Z J, Pan Z Z et al. SiO2 cladding LYSO: Ce scintillation fiber for electron radiation dose measurement[J]. Radiation Measurements, 137, 106432(2020).

[15] Uozumi Y, Yamaguchi Y, Fujii M et al. Responses of PWO, LaBr3:Ce, and LYSO:Ce scintillators to single-electron hits of 5–40 MeV at KU-FEL[J]. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 911, 138-141(2018).

[16] GU Peng, WANG Penggang, GUAN Weiming et al. Research progress on LYSO:Ce scintillation crystals[J]. Journal of Synthetic Crystals, 50, 1858-1869(2021).

[17] ZHOU Wenping, NIU Wei, LIU Xudong et al. Research advances and development direction of scintillation crystal Ce:LYSO[J]. Materials Review, 29, 214-218(2015).

[18] Wan B, Yang F, Ding D Z et al. Effects of yttrium content on intrinsic radioactivity energy spectra of LYSO:Ce crystals[J]. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 1001, 165263(2021).

[19] HUYAN Qi, CAI Zhenbo. Influence of slot region dynamics of Earth radiation belt on the radiation effect of medium-orbit satellites[J]. Spacecraft Environment Engineering, 38, 333-343(2021).

[20] LI Jingyang, ZHAO Heran. Research on radiation hardening technology of packaging[J]. Microprocessors, 42, 21-25(2021).

[21] Millward D G, Strobel D J. The effectiveness of Rad-Pak ICs for space-radiation hardening[C], 913-916(2002).

[22] Akhmetov A O, Sorokoumov G S, Bobrovsky D V et al. The effectiveness of specialized IC packages: experimental and monte-carlo simulation for basic orbits and spacecraft shielding[C], 1-5(2016).

[23] LI Yang. Reinforced (rfd) chip package of radiation resistance[P].

[24] SU Da, GUO Lida, SU Guoyou et al. Electronic device radiation-resistant reinforcing packaging structure[P].

[25] ZHANG Wenjuan, LI Jun, SUN Xiaoming. Ceramic shell capable of enhancing radiation shielding and preparation method thereof[P].

[26] Featherby M, Strobel D J, Layton P J et al. Methods and compositions for ionizing radiation shielding[P].

[27] ZHAO Heran, WANG Jiqiang, CHEN Mingxiang et al. Anti-radiation packaging hardening: a design on electronic radiation shielding[J]. Microprocessors, 42, 1-4(2021).

[28] CAI Yulong, CUI Shuai, LIU Yang et al. Passive shielding against proton and electron in the inner radiation belt[J]. Nuclear Techniques, 46, 020501(2023).

[29] Kartashov D, Shurshakov V. Analysis of space radiation exposure levels at different shielding configurations by ray-tracing dose estimation method[J]. Acta Astronautica, 144, 320-330(2018).

[30] Ahmad S, Chang B, Li B et al. Mass optimization of the radiation shadow shield for space nuclear power system[J]. Progress in Nuclear Energy, 131, 103607(2021).

[31] Colborn B L, Armstrong T W. Mass model of the LDEF satellite spacecraft and experiments for ionizing radiation analyses[J]. Radiation Measurements, 26, 817-823(1996).

[32] WANG Ningyu, GU Shaoxian, CUI Fengjie et al. The study of incident electron beam parameters of XHA600D medical linear accelerator based on Monte Carlo method[J]. Nuclear Physics Review, 39, 519-526(2022).

[33] LAN Ting, CHEN Dong, CHEN Shanqiang et al. Implementation of adjoint/reverse Monte Carlo method in the analysis of satellites radiation[J]. Chinese Journal of Space Science, 35, 203-210(2015).

[34] WU Zhengxin. Research on radiation environment and space dosimetry application in spacecraft[D](2020).

[35] ZHOU Lidan, YAN Chaoxin, YAO Gang et al. Influence of space radiation environment on critical components of spacecraft distributed power system and countermeasures[J]. Transactions of China Electrotechnical Society, 37, 1365-1380(2022).

[36] Inguimbert C, Pierron J, Belhaj M et al. Extrapolated range expression for electrons down to ~10 eV[C].

[37] YUAN Xiaoxiao. Simulation study on positron generation by laser plasma accelerating electron bombardment of solid target[D](2019).