[4] Liang X, Xie X L, Kang J et al. Design and experimental demonstration of a high conversion efficiency OPCPA pre-amplifier for petawatt laser facility[J]. High Power Laser Science and Engineering, 6, e58(2018).
[6] Chen R Y, Wang Y Z, Guo K S et al. Design, fabrication and laser damage comparisons of low-dispersive mirrors[J]. Proceedings of SPIE, 1106, 110630F(2019).
[7] Škoda V, Vanda J. A study of metal-dielectric mirrors technology with regard to the laser-induced damage threshold[J]. Proceedings of SPIE, 1001, 1001424(2016).
[8] Škoda V, Vanda J, Uxa Š. A comparison of LIDT behavior of metal-dielectric mirrors in ns and ps pulse regime at 1030 nm with regard to the coating technology[J]. Proceedings of SPIE, 1044, 1044729(2017).
[9] Csajbók V, Szikszai L, Nagy B J et al. Femtosecond damage resistance of femtosecond multilayer and hybrid mirrors[J]. Optics Letters, 41, 3527(2016).
[11] Zhang J L, Bu X Q, Jiao H F et al. Laser damage properties of broadband low-dispersion mirrors in sub-nanosecond laser pulse[J]. Optics Express, 25, 305-312(2017).
[12] Bellum J C, Winstone T B, Field E S et al. Broad bandwidth high reflection coatings for petawatt class lasers: femtosecond pulse laser damage tests, and measurement of group delay dispersion[J]. Proceedings of SPIE, 1008, 100840J(2017).
[13] Patel D, Schiltz D, Langton P F et al. Improvements in the laser damage behavior of Ta2O5/SiO2 interference coatings by modification of the top layer design[J]. Proceedings of SPIE, 8885, 888522(2013).
[14] Bellum J C, Field E S, Winstone T B et al. Low group delay dispersion optical coating for broad bandwidth high reflection at 45° incidence, P polarization of femtosecond pulses with 900 nm center wavelength[J]. The Coatings, 6, 11(2016).
[15] Schiltz D, Patel D, Baumgarten C et al. Strategies to increase laser damage performance of Ta2O5/SiO2 mirrors by modifications of the top layer design[J]. Applied Optics, 56, C136(2017).