[1] D. Holder, A. Leis, M. Buser, R. Weber, T. Graf. High-quality net shape geometries from additively manufactured parts using closed-loop controlled ablation with ultrashort laser pulses. Adv. Opt. Technol., 9, 101(2020).
[2] H. Büttner, K. Michael, J. Gysel, P. Gugger, S. Saurenmann, G. de Bortoli, J. Stirnimann, K. Wegener. Innovative micro-tool manufacturing using ultra-short pulse laser ablation. J. Mater. Process. Technol., 285, 116766(2020).
[3] B. Huis in ’t Veld, L. Overmeyer, M. Schmidt, K. Wegener, A. Malshe, P. Bartolo. Micro additive manufacturing using ultra short laser pulses. CIRP Ann. Manuf. Technol., 64, 701(2015).
[4] P. P. Geiko, A. Tikhomirov. Remote measurement of chemical warfare agents by differential absorption CO2 lidar. Opt. Mem. Neural Netw., 20, 71(2011).
[5] D. C. Dumitras, S. Banita, A. M. Bratu, R. Cernat, D. C. A. Dutu, C. Matei, M. Patachia, M. Petrus, C. Popa. Ultrasensitive CO2 laser photoacoustic system. Infrared Phys. Technol., 53, 308(2010).
[6] P. P. Geiko, A. Tikhomirov. Remote measurement of chemical warfare agents by differential absorption CO2 lidar. Opt. Mem. Neural Netw., 20, 71(2011).
[7] S. Nikiforov, Y. Simanovsky, A. Pento, K. Moshkunov, N. Gorbatova, S. Zolotov, S. Alimpiev. Pulsed transverse discharge CO2 laser for medical applications. International Conference Laser Optics (LO)(2016).
[8] R. H. M. A. Schleijpen, F. J. M. van Putten. Using a CO2 laser for PIR-detector spoofing. Proc. SPIE, 9989, 99890K(2016).
[9] Y. Zhang, H. Wang, L. Liu, Y. Ma, B. Shen, G. Zhang, M. Huang, A. Bonasera, W. Wang, J. Xu, S. Li, G. Fan, X. Cao, Y. Yu, C. Fu, J. He, S. Zhang, X. Hu, X. Li, Z. Hao, J. Wang, H. Xue, H. Fu. Primary yields of protons measured using CR-39 in laser-induced deuteron–deuteron fusion reactions. Nucl. Sci. Tech., 31, 62(2020).
[10] S. S. Perrotta, A. Bonasera. Fusion hindrance effects in laser-induced non-neutral plasmas. Nucl. Phys. A, 989, 168(2019).
[11] R. Snyder. A proliferation assessment of third generation laser uranium enrichment technology. Sci. Glob. Sec., 24, 68(2016).
[12] V. K. Saini, S. Talwar, V. V. V. Subrahmanyam, S. K. Dixit. Laser assisted isotope separation of lithium by two-step photoionization using time of flight mass-spectrometer. Opt. Laser Technol., 111, 754(2019).
[13] J. C. Balzer, T. Schlauch, A. Klehr, G. Erbert. High peak power pulses from dispersion optimized mode-locked semiconductor laser. Electron. Lett., 49, 838(2013).
[14] Y. R. Yuzaile, N. A. Awang, N. U. H. H. Zalkepali, Z. Zakaria, A. A. Latif, A. N. Azmi, F. S. Abdul Hadi. Pulse compression in Q-switched fiber laser by using platinum as saturable absorber. Optik, 179, 977(2019).
[15] H. V. Bergmann, F. Morkel. Continuously wavelength tunable high pressure CO2 lasers. Proc. SPIE, 9255, 92551Y(2015).
[16] J. Gilbert, J. L. Lachambre, F. Rheault, R. Fortin. Dynamics of the CO2 atmospheric pressure laser with transverse pulse excitation. Can. J. Phys., 50, 2523(1972).
[17] K. J. Andrews, P. E. Dyer, D. J. James. A rate equation model for the design of TEA CO2 oscillators. J. Phys. E, 8, 493(1975).
[18] O. Richter, R. Seppelt, D. Sndgerath. Computer Modeling(2006).
[19] J. N. Elgin. Computer modeling of gas lasers. Electron. Power UK, 25, 441(1979).
[20] M. Kimmit. Book Review: The CO2 laser. By W. J. Witteman. Springer Series in Optical Sciences, Vol. 53. Springer-Verlag, 1987. 309 pp. Price: DM 98 (hard cover). Opt. Lasers Eng., 11, 66(1989).
[21] A. R. Davies, K. Smith, R. M. Thomson. TLASER—a CO2 laser kinetics code. Comput. Phys. Commun., 10, 117(1975).