[1] CHEN M Y, OUYANG D X, LIU J, et al. Investigation on thermal and fire propagation behaviors of multiple lithium-ion batteries within the package[J]. Applied thermal engineering, 2019, 157:113750.

[2] WANG X B, WU F T, YAO M H. A life-prediction method for lithium-ion batteries based on a fusion model and an attention mechanism[J]. Optoelectronics letters, 2020, 16(6):410-417.

[3] ZHANG C, GUO Y, WANG C, et al. A new design of experiment method for model parametrisation of lithium ion battery[J]. Journal of energy storage, 2022, 50: 104301.

[4] FREDRIK L, SIMON B, MAURIZIO F, et al. Gas explosions and thermal runaways during external heating abuse of commercial lithium-ion graphite-LiCoO2 cells at different levels of ageing[J]. Journal of power sources, 2018, 373:220-231.

[5] FERNANDES Y, BRY A, PERSIS S. Identification and quantification of gases emitted during abuse tests by overcharge of a commercial Li-ion battery[J]. Journal of power sources, 2018, 389:106-119.

[6] KIM J Y, WANG Z L, LEE S M, et al. Failure analysis of thermally abused lithium-ion battery cell by microscopy, electrochemical impedance spectroscopy, and acoustic emission[J]. Microelectronics reliability, 2019, 100-101:113363.

[7] BEN R, NURIA G A. A review of gas evolution in lithium ion batteries[J]. Energy reports, 2020, 6(Supl.5): 10-18.

[8] WANG Q S, MAO B B, STANISLAV I, et al. A review of lithium-ion battery failure mechanisms and fire prevention strategies[J]. Progress in energy and combustion science, 2019, 73:95-131.

[9] MANUEL N V. Fundamentals of Mie scattering[M]//Woodhead publishing series in electronic and optical materials. Cambridge :Woodhead Publishing, 2014, 202:39-72.

[10] ZHANG H, NIE W, LIANG Y, et al. Development and performance detection of higher precision optical sensor for coal dust concentration measurement based on Mie scattering theory[J]. Optics and lasers in engineering, 2021, 144:106642.