[1] Zhou J, Qiu S Y, Du P N et al. Research progress in the FeCrAl alloys for accident tolerant fuel cladding[J]. Materials Review, 31, 47-51(2017).

[2] Li H B, He H, Ye G A et al. An advanced head-end process for reprocessing of spent fuel by high temperature vol-oxidation treatment[J]. Atomic Energy Science and Technology, 49, 780-786(2015).

[3] Zhang Z F, He J Y, Zhu Z W et al. Neptunium control in co-decontamination step of purex process[J]. Journal of Nuclear Fuel Cycle and Environment, 8, 165-170(2002).

[4] Li J Y, Shi L, Hu Y T. Some considerations on the construction of a spent nuclear fuel reprocessing plant in China[J]. Journal of Nuclear and Radiochemistry, 33, 204-210(2011).

[5] Zhang X C, Qian J, Fu Q et al. Cutting of PBO fiber-reinforced composites using picosecond lasers[J]. Chinese Journal of Lasers, 47, 0402003(2020).

[6] Biswas R, Kuar A S, Mitra S. Influence of machining parameters on surface roughness in Nd∶YAG laser micro-cutting of alumina-aluminium interpenetrating phase composite[J]. International Journal of Surface Science and Engineering, 2, 252-264(2008).

[7] Adalarasan R, Santhanakumar M, Rajmohan M. Optimization of laser cutting parameters for Al6061/SiCp/Al2O3 composite using grey based response surface methodology (GRSM)[J]. Measurement, 73, 596-606(2015).

[8] Shin J S, Oh S Y, Park H et al. Underwater cutting of 50 and 60  mm thick stainless steel plates using a 6-kW fiber laser for dismantling nuclear facilities[J]. Optics & Laser Technology, 115, 1-8(2019).

[9] Oh S Y, Shin J S, Kim T S et al. Effect of nozzle types on the laser cutting performance for 60-mm-thick stainless steel[J]. Optics & Laser Technology, 119, 105607(2019).

[10] Shen Y P, Chen C, Gao M et al. Technological characteristics in fiber laser cutting of medium-thickness aluminum alloy sheet[J]. Chinese Journal of Lasers, 46, 0102008(2019).

[11] Tahir B A, Ahmed R, Ashiq M G B et al. Cutting of nonmetallic materials using Nd∶YAG laser beam[J]. Chinese Physics B, 21, 290-293(2012).

[12] Zhou B H, Mahdavian S M. Experimental and theoretical analyses of cutting nonmetallic materials by low power CO2-laser[J]. Journal of Materials Processing Technology, 146, 188-192(2004).

[13] Ji L F, Yan Y Z, Bao Y et al. Crack-free cutting of thick and dense ceramics with CO2 laser by single-pass process[J]. Optics and Lasers in Engineering, 46, 785-790(2008).

[14] Beausoleil C, Yazdani S H, Katz Z et al. Deep and high precision cutting of alumina ceramics by picosecond laser[J]. Ceramics International, 46, 15285-15296(2020).

[15] Luo Y H, Wang X Y. Morphology investigation of removal particles during laser cutting of Al2O3 ceramics based on vapor-to-melt ratio[J]. Journal of Materials Processing Technology, 255, 340-346(2018).

[16] Ye S L, Ma J S, Huang X. Simulation of the temperature field in laser cutting of brittle materials[J]. Optical Technique, 33, 599-601, 605(2007).

[17] Yuan W. Technical research of YAG laser cutting sheet steels[D](2014).

[18] Saternus Z, Piekarska W, Kubiak M et al. Numerical modeling of cutting process of steel sheets using a laser beam[J]. MATEC Web of Conferences, 254, 08004(2019).

[19] Ren N, Liu G D, Li X M et al. Simulation analysis of temperature field of laser cut NdFeB magnetic material[J]. Manufacturing Technology & Machine Tool, 25-29(2020).

[20] Yu D Y, Wang X Y. Temperature field simulation of single-layer carbon fiber reinforced plastics in multi-directional laser cutting[J]. Laser & Optoelectronics Progress, 54, 111409(2017).

[21] Carbajo J J, Yoder G L, Popov S G et al. A review of the thermophysical properties of MOX and UO2 fuels[J]. Journal of Nuclear Materials, 299, 181-198(2001).

[22] Fink J K. Thermophysical properties of uranium dioxide[J]. Journal of Nuclear Materials, 279, 1-18(2000).