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Kansai Photon Science Institute   |   The 29th KPSI Seminar High Average Power Ultrafast Thin-Disk Amplifiers

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Kansai Photon Science Institute >> KPSI Seminar >> High Average Power Ultrafast Thin-Disk Amplifiers

 

Seminar

The 29th KPSI Seminar

High Average Power Ultrafast Thin-Disk Amplifiers

 

Presentor Dr. Thomas Metzger
(TRUMPF Scientific Lasers GmbH + Co. KG, Feringastrasse 10a, 85774 Unterfoehring, Germany)
Jobstatus Chief Technology Officer
Place ITBL G201 room (KPSI)
Date 13:00 - (Thu.) Oct 12, 2017
Language English
abstract [PDFfile/109KB]

High Average Power Ultrafast Thin-Disk Amplifiers

Dr. Thomas Metzger
(TRUMPF Scientific Lasers GmbH + Co. KG, Feringastrasse 10a, 85774 Unterfoehring, Germany)

abstract

Thin-disk regenerative amplifiers are routinely used for generating multi-millijoule pulses with durations of < 2 ps at kilohertz repetition rates [1-3] and demonstrated recently record values of 220 mJ at 1 kHz [4]. Derived from industrial micro machining lasers [5] and high power cw lasers for laser cutting and laser welding [6], this technology was initially developed for pumping optical parametric chirped pulse amplifiers (OPCPA) [7,8] revolutionizing attosecond technology [9]. Latest results demonstrate that kilohertz thin-disk regenerative amplifiers are scalable beyond the kilowatt average power level uncovering new perspectives of applications. Laser based lightning rod [10,11], X-ray lasers [12] and inverse Compton scattering [13] are among them. The principle of these thin-disk amplifiers operated at ambient temperature is based on chirped pulse amplification. This lecture gives an introduction into ultrafast high power thin-disk laser technology and the current development at TRUMPF Scientific Lasers.

 

References:

[1] T. Metzger, A. Schwarz, C. Y. Teisset, D. Sutter, A. Killi, R. Kienberger, and F. Krausz, “High-repetition-rate picosecond pump laser based on a Yb:YAG disk amplifier for optical parametric amplification,” Opt. Lett. 34, 2123-2125 (2009).

[2] C. Teisset, M. Schultze, R. Bessing, M. Haefner, S. Prinz, D. Sutter, and T. Metzger, “300 W Picosecond Thin-Disk Regenerative Amplifier at 10 kHz Repetition Rate,” in Advanced Solid-State Lasers Congress Postdeadline, G. Huber and P. Moulton, eds., OSA Postdeadline Paper Digest (online) (Optical Society of America, 2013), paper JTh5A.1.

[3] H. Fattahi, A. Alismail, H. Wang, J. Brons, O. Pronin, T. Buberl, L. Vámos, G. Arisholm, A. Azzeer, and F. Krausz, “High-power, 1-ps, all-Yb:YAG thin-disk regenerative amplifier,” Opt. Lett. 41, 1126-1129 (2016).

[4] S. Klingebiel, M. Schultze, C. Teisset, R. Bessing, M. Haefner, S. Prinz, M. Gorjan, D. Sutter, K. Michel, H. Barros, z. Major, F. Krausz, and T. Metzger, “220mJ Ultrafast Thin-Disk Regenerative Amplifier,” in CLEO: 2015, OSA Technical Digest (online) (Optical Society of America, 2015), paper STu4O.2.

[5] O. H. Heckl, J. Kleinbauer, D. Bauer, S. Weiler, T. Metzger, and D. H. Sutter, “Ultrafast Thin-Disk Lasers,” in “Ultrashort Pulse Laser Technology,”, vol. 195, S. Nolte, F. Schrempel, and F. Dausinger, eds. (Springer International Publishing, Cham, 2016), pp. 93–115.

[6] https://www.trumpf.com/en_US/products/lasers/disk-lasers/trudisk/

[7] H. Fattahi, H. Barros, M. Gorjan, T. Nubbemeyer, B. Alsaif, C. Teisset, M. Schultze, S. Prinz, M. Haefner, M. Ueffing, A. Alismail, L. Vámos, A. Schwarz, O. Pronin, J. Brons, X. Geng, G. Arisholm, M. Ciappina, V. Yakovlev, D. Kim, A. Azzeer, N. Karpowicz, D. Sutter, Z. Major, T. Metzger, and F. Krausz, “Third-generation femtosecond technology,” Optica 1, 45-63 (2014).

[8] S. Prinz, M. Haefner, C. Teisset, R. Bessing, K. Michel, Y. Lee, X. Geng, S. Kim, D. Kim, T. Metzger, and M. Schultze, “CEP-stable, sub-6 fs, 300-kHz OPCPA system with more than 15 W of average power,” Opt. Express 23, 1388-1394 (2015).

[9] F. Krausz, “The birth of attosecond physics and its coming of age,” Physica Scripta 91, 063011 (2016).

[10] A. Houard, V. Jukna, G. Point, Y. André, S. Klingebiel, M. Schultze, K. Michel, T. Metzger, and A. Mysyrowicz, “Study of filamentation with a high power high repetition rate ps laser at 1.03 µm,” Opt. Express 24, 7437-7448 (2016).

[11] E. Schubert, L. de la Cruz, D. Mongin, S. Klingbiel, M. Schultze, T. Metzger, K. Michel, J. Kasparian, and J.-P. Wolf, “Dual-scale turbulence in high-average power laser filaments,” Phys. Rev. A 94, 043808 (2016).

[12] R. Keenan, J. Dunn, P. K. Patel, D. F. Price, R. F. Smith, and V. N. Shlyaptsev, “High-repetition-rate grazing-incidence pumped X-ray laser operating at 18.9 nm,“ Phys. Rev. Lett. 94, 103901 (2005).

[13] W. S. Graves, J. Bessuille, P. Brown, S. Carbajo, V. Dolgashev, K.-H. Hong, E. Ihloff, B. Khaykovich, H. Lin, K. Murari, E. A. Nanni, G. Resta, S. Tantawi, L. E. Zapata, F. X. Kärtner, and D. E. Moncton, “Compact x-ray source based on burst-mode inverse Compton scattering at 100 kHz,” Phys. Rev. ST Accel. Beams 17, 120701 (2014).

 

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