[1] C. Danson, D. Hillier, N. Hopps, D. Neely. Petawatt class lasers worldwide. High Power Laser Sci. Eng., 3, e3(2015).
[2] K. Nakamura, H.-S. Mao, A. J. Gonsalves, H. Vincenti, D. E. Mittelberger, J. Daniels, A. Magana, C. Toth, W. P. Leemans. Diagnostics, control and performance parameters for the BELLA high repetition rate petawatt class laser. IEEE J. Quantum Electron., 53, 1200121(2017).
[3] H. Kiriyama, A. S. Pirozhkov, M. Nishiuchi, Y. Fukuda, K. Ogura, A. Sagisaka, Y. Miyasaka, M. Mori, H. Sakaki, N. P. Dover, K. Kondo, J. K. Koga, T. Z. Esirkepov, M. Kando, K. Kondo. High-contrast high-intensity repetitive petawatt laser. Opt. Lett., 43, 2595(2018).
[4] F. Lureau, G. Matras, O. Chalus, C. Derycke, T. Morbieu, C. Radier, O. Casagrande, S. Laux, S. Ricaud, G. Rey, A. Pellegrina, C. Richard, L. Boudjemaa, C. Simon-Boisson, A. Baleanu, R. Banici, A. Gradinariu, C. Caldararu, B. De Boisdeffre, P. Ghenuche, A. Naziru, G. Kolliopoulos, L. Neagu, R. Dabu, I. Dancus, D. Ursescu. High-energy hybrid femtosecond laser system demonstrating 2 × 10 PW capability. High Power Laser Sci. Eng., 8, e43(2020).
[5] W. Li, Z. Gan, L. Yu, C. Wang, Y. Liu, Z. Guo, L. Xu, M. Xu, Y. Hang, Y. Xu, J. Wang, P. Huang, H. Cao, B. Yao, X. Zhang, L. Chen, Y. Tang, S. Li, X. Liu, S. Li, M. He, D. Yin, X. Liang, Y. Leng, R. Li, Z. Xu. 339 J high-energy Ti:sapphire chirped-pulse amplifier for 10 PW laser facility. Opt. Lett., 43, 5681(2018).
[6] Z. Zhang, F. Wu, J. Hu, X. Yang, J. Gui, P. Ji, X. Liu, C. Wang, Y. Liu, X. Lu, Y. Xu, Y. Leng, R. Li, Z. Xu. The 1 PW/0.1 Hz laser beamline in SULF facility. High Power Laser Sci. Eng., 8, e4(2020).
[7] T. J. Yu, S. K. Lee, J. H. Sung, J. W. Yoon, T. M. Jeong, J. Lee. Generation of high-contrast, 30 fs, 1.5 PW laser pulses from chirped-pulse amplification Ti:sapphire laser. Opt. Express, 20, 10807(2012).
[8] J. W. Yoon, Y. G. Kim, I. W. Choi, J. H. Sung, H. W. Lee, S. K. Lee, C. H. Nam. Realization of laser intensity over 1023 W/cm2. Optica, 8, 630(2021).
[9] D.-Q. Wen, P. Zhang, J. Krek, Y. Fu, J. P. Verboncoeur. Higher harmonics in multipactor induced plasma ionization breakdown near a dielectric surface. Phys. Rev. Lett., 129, 045001(2022).
[10] H. Kiriyama, Y. Miyasaka, A. Sagisaka, K. Ogura, M. Nishiuchi, A. S. Pirozhkov, Y. Fukuda, M. Kando, K. Kondo. Experimental investigation on the temporal contrast of pre-pulses by post-pulses in a petawatt laser facility. Opt. Lett., 45, 1100(2020).
[11] L. Ranc, C. Le Blanc, N. Lebas, L. Martin, J. P. Zou, F. Mathieu, C. Radier, S. Ricaud, F. Druon, D. Papadopoulos. Improvement in the temporal contrast in the tens of ps range of the multi-PW Apollon laser front-end. Opt. Lett., 45, 4599(2020).
[12] K. Osvay, M. Csatári, I. N. Ross, A. Persson, C.-G. Wahlström. On the temporal contrast of high intensity femtosecond laser pulses. Laser Part. Beams, 23, 327(2005).
[13] M. Kaluza, J. Schreiber, M. I. Santala, G. D. Tsakiris, K. Eidmann, J. Meyer-ter-Vehn, K. J. Witte. Influence of the laser prepulse on proton acceleration in thin-foil experiments. Phys. Rev. Lett., 93, 045003(2004).
[14] A. Jullien, O. Albert, F. Burgy, G. Hamoniaux, J.-P. Rousseau, J.-P. Chambaret, F. Augé-Rochereau, G. Chériaux, J. Etchepare, N. Minkovski, S. M. Saltiel. 10−10 temporal contrast for femtosecond ultraintense lasers by cross-polarized wave generation. Opt. Lett., 30, 920(2005).
[15] C. Dorrer, I. A. Begishev, A. V. Okishev, J. D. Zuegel. High-contrast optical-parametric amplifier as a front end of high-power laser systems. Opt. Lett., 32, 2143(2007).
[16] C. Thaury, F. Quéré, J. P. Geindre, A. Levy, T. Ceccotti, P. Monot, M. Bougeard, F. Réau, P. d’Oliveira, P. Audebert, R. Marjoribanks, P. Martin. Plasma mirrors for ultrahigh-intensity optics. Nat. Phys., 3, 424(2007).
[17] A. Lévy, T. Ceccotti, P. D’Oliveira, F. Réau, M. Perdrix, F. Quéré, P. Monot, M. Bougeard, H. Lagadec, P. Martin. Double plasma mirro for ultrahigh temporal contrast ultraintense laser pulses. Opt. Lett., 32, 310(2007).
[18] Y. Nomura, L. Veisz, K. Schmid, T. Wittmann, J. Wild, F. Krausz. Time-resolved reflectivity measurements on a plasma mirror with few-cycle laser pulses. New J. Phys., 9, 9(2007).
[19] S. Inoue, K. Maeda, S. Tokita, K. Mori, K. Teramoto, M. Hashida, S. Sakabe. Single plasma mirror providing 104 contrast enhancement and 70% reflectivity for intense femtosecond lasers. Appl. Opt., 55, 5647(2016).
[20] L. Obst, J. Metzkes-Ng, S. Bock, G. E. Cochran, T. E. Cowan, T. Oksenhendler, P. L. Poole, I. Prencipe, M. Rehwald, C. Rödel, H. P. Schlenvoigt, U. Schramm, D. W. Schumacher, T. Ziegler, K. Zeil. On-shot characterization of single plasma mirror temporal contrast improvement. Plasma Phys. Control. Fusion, 60, 054007(2018).
[21] B. Dromey, S. Kar, M. Zepf, P. Foster. The plasma mirror—a subpicosecond optical switch for ultrahigh power lasers. Rev. Sci. Instrum., 75, 645(2004).
[22] I. W. Choi, C. Jeon, S. G. Lee, S. Y. Kim, T. Y. Kim, I. J. Kim, H. W. Lee, J. W. Yoon, J. H. Sung, S. K. Lee, C. H. Nam. Highly efficient double plasma mirror producing ultrahigh-contrast multi-petawatt laser pulses. Opt. Lett., 45, 6342(2020).
[23] X. G. Ge, Y. Fang, S. Yang, W. Wei, F. Liu, P. Yuan, J. Ma, L. Zhao, X. Yuan, J. Zhang. Characterization and application of plasma mirror for ultra-intense femtosecond lasers. Chin. Opt. Lett., 16, 013201(2018).
[24] C. Rödel, M. Heyer, M. Behmke, M. Kübel, O. Jäckel, W. Ziegler, D. Ehrt, M. C. Kaluza, G. G. Paulus. High repetition rate plasma mirror for temporal contrast enhancement of terawatt femtosecond laser pulses by three orders of magnitude. Appl. Phys. B, 103, 295(2011).
[25] G. G. Scott, V. Bagnoud, C. Brabetz, R. J. Clarke, J. S. Green, R. I. Heathcote, H. W. Powell, B. Zielbauer, T. D. Arber, P. McKenna, D. Neely. Optimization of plasma mirror reflectivity and optical quality using double laser pulses. New J. Phys., 17, 033027(2015).
[26] M. H. Xu, Y. T. Li, X. H. Yuan, Q. Z. Yu, S. J. Wang, W. Zhao, X. L. Wen, G. C. Wang, C. Y. Jiao, Y. L. He, S. G. Zhang, X. X. Wang, W. Z. Huang, Y. Q. Gu, J. Zhang. Effects of shock waves on spatial distribution of proton beams in ultrashort laser-foil interactions. Phys. Plasmas, 13, 104507(2006).
[27] W. P. Wang, C. Jiang, H. Dong, X. M. Lu, J. F. Li, R. J. Xu, Y. J. Sun, L. H. Yu, Z. Guo, X. Y. Liang, Y. X. Leng, R. X. Li, Z. Z. Xu. Hollow plasma acceleration driven by a relativistic reflected hollow laser. Phys. Rev. Lett., 125, 034801(2020).
[28] R. Ramis, K. Eidmann, J. Meyer-ter-Vehn, S. Hüller. Multi-fs–a computer code for laser–plasma interaction in the femtosecond regime. Comput. Phys. Commun., 183, 637(2012).
[29] Y. Kuramitsu, T. Minami, T. Hihara, K. Sakai, T. Nishimoto, S. Isayama, Y. T. Liao, K. T. Wu, W. Y. Woon, S. H. Chen, Y. L. Liu, S. M. He, C. Y. Su, M. Ota, S. Egashira, A. Morace, Y. Sakawa, Y. Abe, H. Habara, R. Kodama, L. N. K. Döhl, N. Woolsey, M. Koenig, H. S. Kumar, N. Ohnishi, M. Kanasaki, T. Asai, T. Yamauchi, K. Oda, Ko. Kondo, H. Kiriyama, Y. Fukuda. Robustness of large-area suspended graphene under interaction with intense laser. Sci. Rep., 12, 2346(2022).
[30] T. D. Arber, K. Bennett, C. S. Brady, A. Lawrence-Douglas, M. G. Ramsay, N. J. Sircombe, P. Gillies, R. G. Evans, H. Schmitz, A. R. Bell, C. P. Ridgers. Contemporary particle-in-cell approach to laser-plasma modelling. Plasma Phys. Control. Fusion, 57, 113001(2015).
[31] A. A. Andreev, R. Sonobe, S. Kawata, S. Miyazaki, K. Sakai, K. Miyauchi, T. Kikuchi, K. Platonov, K. Nemoto. Effect of a laser prepulse on fast ion generation in the interaction of ultra-short intense laser pulses with a limited-mass foil target. Plasma Phys. Control. Fusion, 48, 1605(2006).
[32] W. P. Wang, H. Zhang, B. Wu, C. Y. Jiao, Y. C. Wu, B. Zhu, K. G. Dong, W. Hong, Y. Q. Gu, B. F. Shen, Y. Xu, Y. X. Leng, R. X. Li, Z. Z. Xu. Generation of low-divergence megaelectronvolt ion beams from thin foil irradiated with an ultrahigh-contrast laser. Appl. Phys. Lett., 101, 214103(2012).
[33] G. G. Scott, G. F. H. Indorf, M. A. Ennen, P. Forestier-Colleoni, S. J. Hawkes, L. Scaife, M. Sedov, D. R. Symes, C. Thornton, F. Beg, T. Ma, P. McKenna, A. A. Andreev, U. Teubner, D. Neely. Kinematics of femtosecond laser-generated plasma expansion: determination of sub-micron density gradient and collisionality evolution of over-critical laser plasmas. Phys. Plasmas, 28, 093109(2021).