L. Chemartin, P. Lalande, B. Peyrou, A. Chazottes, and P. Q. Elias, Direct Effects of Aircraft Structure: Analysis of the Thermal, Electrical and Mechanical Constraints, Journal of Aerospace Lab, issue.5, 2012.
URL : https://hal.archives-ouvertes.fr/hal-01184416

R. Chippendale, Modelling of the Thermal Chemical Damage Caused to Carbon Fibre Composites, 2013.

Q. Dong, Y. Guo, X. Sun, and Y. Jia, Coupled Electrical-Thermal-Pyrolytic Analysis of Carbon Fiber/Epoxy Composites Subjected to Lightning Strike, Polymer, vol.56, pp.385-94, 2015.

T. Ogasawara, Y. Hirano, and A. Yoshimura, Coupled Thermal-electrical Analysis for Carbon Fiber/Epoxy Composites Exposed to Simulated Lightning Current, Composites Part A: Applied Science and Manufacturing, vol.41, issue.8, pp.973-81, 2010.

Y. Wang and O. I. Zhupanska, Evaluation of the Thermal Damage in Glass Fiber Polymer-Matrix Composites in Wind Turbine Blades Subjected to Lightning Strike, Proceedings of American Society for Composites, 29th Annual Technical Conference, 2014.

F. S. Wang, Y. Y. Ji, X. S. Yu, H. Chen, and Z. F. Yue, Ablation Damage Assessment of Aircraft Carbon Fiber/Epoxy Composite and Its Protection Structures Suffered from Lightning Strike, Composite Structures, vol.145, pp.226-267, 2016.

A. Bigand and Y. Duval, Quantification of the mechanical impact of lightning strike protection explosion confined by thick paint, Int. Conf. on Lightning and Static Electricity, p.2017

. Eurocae, ED-84 -Aircraft lightning environment and related test waveforms, 2013.

R. Sousa-martins, Experimental and theoretical studies of lightning arcs and their interaction with aeronautical materials, 2016.

A. Bigand, Estimation of the load produced by the electro-thermal behaviour of lightning strike protection layers on a composite panel, ECCM18 -18th European Conference on Composite Materials, 2018.
URL : https://hal.archives-ouvertes.fr/hal-02152507

. Rodríguez, Dynamics of a Shock Wave with Time Dependent Energy Release Generated by an Exploding Wire in Air, Physics of Plasmas, vol.25, issue.11, 2018.

. Li, Study of the Shock Waves Characteristics Generated by Underwater Electrical Wire Explosion », Journal of Applied Physics, vol.118, issue.2, 2015.

C. , « Numerical Model for Electrical Explosion of Copper Wires in Water, Journal of Applied Physics, vol.120, p.20, 2016.

, Ivanenkov et al« Current Shunting and Formation of Stationary Shock Waves during Electric Explosions of Metal Wires in Air, Plasma Physics Reports, vol.36, issue.1, 2010.

. Han, Relationship between Energy Deposition and Shock Wave Phenomenon in an Underwater Electrical Wire Explosion, vol.24, 2017.

, Grinenko et al « Efficiency of the Shock Wave Generation Caused by Underwater Electrical Wire Explosion », Journal of Applied Physics, vol.100, issue.11, 2006.

F. Soulas, C. Espinosa, F. Lachaud, S. Guinard, B. Lepetit et al., A method to replace lightning strike tests by ball impacts in the design process of lightweight composite aircraft panels, International Journal of Impact Engineering, vol.111, pp.165-176, 2018.
URL : https://hal.archives-ouvertes.fr/hal-01940478

B. Lepetit, F. Soulas, S. Guinard, I. Revel, and G. Peres, Analysis of composite panel damages due to a lightning strike: mechanical effects, Int. Conf. on Lightning and Static Electricity, 2013.

Z. Q. Liu, Z. F. Yue, F. S. Wang, and Y. Y. Ji, Combining Analysis of Coupled Electrical-Thermal and BLOW-OFF Impulse Effects on Composite Laminate Induced by Lightning Strike, Applied Composite Materials, vol.22, issue.2, pp.189-207, 2015.

C. Karch, R. Honke, J. Steinwandel, and K. W. Dittrich, Contributions of lightning current pulses to mechanical damage of CFRP structures, Int. Conf. on Lightning and Static Electricity, 2015.

Z. Hashin, Failure Criteria for Unidirectional Fiber Composites, Journal of Applied Mechanics, vol.47, pp.329-334, 1980.

F. Lago, Measurement by a digital image correlation technique of the deflection of panels submitted to lightning pulse currents, Int. Conf. on Lightning and Static Electricity, 2011.