New high-power laser facility PALS—prospects for laser–plasma research

B. RUS; K. ROHLENA; J. SKÁLA; B. KRÁLIKOVÁ; K. JUNGWIRTH; J. ULLSCHMIED; K.J. WITTE; H. BAUMHACKER

doi:10.1017/S0263034699172045

Abstract

In this paper, we report on a new laser facility called PALS (Prague Asterix Laser System), which is currently under construction, and which will house the high-power iodine laser Asterix IV. Upon its completion in late 1999, the PALS facility will be capable of providing single- or multiple-pulse irradiation with a variable pulse duration ranging from 100 to 500 ps. Wavelengths available will be 1.315 μm, 658 nm, and 438 nm. The system will provide one main beam with energy up to 1200 J and two smaller auxiliary beams with a combined energy of up to 100 J. A wide variety of geometries and variable pulse timings is available. We assess PALS' potential for investigating the physics of laser plasmas in inertial confinement fusion, the development and applications of X-ray lasers, X-ray spectroscopy, and radiation transport, using multiple-pulse and extended beam capability.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Matousek, P. Rus, B. and Ross, I.N. 2000. Design of a multi-petawatt optical parametric chirped pulse amplifier for the iodine laser ASTERIX IV. IEEE Journal of Quantum Electronics, Vol. 36, Issue. 2, p. 158.

Jungwirth, K. Cejnarova, A. Juha, L. Kralikova, B. Krasa, J. Krousky, E. Krupickova, P. Laska, L. Masek, K. Mocek, T. Pfeifer, M. Präg, A. Renner, O. Rohlena, K. Rus, B. Skala, J. Straka, P. and Ullschmied, J. 2001. The Prague Asterix Laser System. Physics of Plasmas, Vol. 8, Issue. 5, p. 2495.

Rohlena, K. Jungwirth, K. Rus, B. Straka, P. Turcicova, H. and Ullschmied, J. 2002. Prague ASTERIX Laser System (PALS) - Physical Program and Plans.

Rus, B Mocek, T Pr g, A R Kozlov, M Hude ek, M Jamelot, G Carillon, A Ros, D Lagron, J-C Joyeux, D and Phalippou, D 2002. Multi-millijoule, deeply saturated x-ray laser at 21.2 nm for applications in plasma physics. Plasma Physics and Controlled Fusion, Vol. 44, Issue. 12B, p. B207.

Rus, B. Mocek, T. Präg, A. R. Kozlová, M. Jamelot, G. Carillon, A. Ros, D. Joyeux, D. and Phalippou, D. 2002. Multimillijoule, highly coherent x-ray laser at 21 nm operating in deep saturation through double-pass amplification. Physical Review A, Vol. 66, Issue. 6,

Mocek, Tomáš Rus, Bedřich Präg, Ansgar R. Kozlová, Michaela Jamelot, Gérard Carillon, Antoine and Ros, David 2003. Beam properties of a deeply saturated, half-cavity zinc soft-x-ray laser. Journal of the Optical Society of America B, Vol. 20, Issue. 6, p. 1386.

FIEDOROWICZ, HENRYK 2005. Generation of soft X-rays and extreme ultraviolet (EUV) using a laser-irradiated gas puff target. Laser and Particle Beams, Vol. 23, Issue. 03,

Ferus, M. Kubelík, P. and Civiš, S. 2011. Laser Spark Formamide Decomposition Studied by FT-IR Spectroscopy. The Journal of Physical Chemistry A, Vol. 115, Issue. 44, p. 12132.

Ferus, Martin Civiš, Svatopluk Mládek, Arnošt Šponer, Jiří Juha, Libor and Šponer, Judit E. 2012. On the Road from Formamide Ices to Nucleobases: IR-Spectroscopic Observation of a Direct Reaction between Cyano Radicals and Formamide in a High-Energy Impact Event. Journal of the American Chemical Society, Vol. 134, Issue. 51, p. 20788.

Novák, Ondřej Divoký, Martin Turčičová, Hana and Straka, Petr 2013. Design of a petawatt optical parametric chirped pulse amplification upgrade of the kilojoule iodine laser PALS. Laser and Particle Beams, Vol. 31, Issue. 2, p. 211.

Danson, Colin Hillier, David Hopps, Nicholas and Neely, David 2015. Petawatt class lasers worldwide. High Power Laser Science and Engineering, Vol. 3, Issue. ,

Danson, Colin N. White, Malcolm Barr, John R. M. Bett, Thomas Blyth, Peter Bowley, David Brenner, Ceri Collins, Robert J. Croxford, Neal Dangor, A. E. Bucker Devereux, Laurence Dyer, Peter E. Dymoke-Bradshaw, Anthony Edwards, Christopher B. Ewart, Paul Ferguson, Allister I. Girkin, John M. Hall, Denis R. Hanna, David C. Harris, Wayne Hillier, David I. Hooker, Christopher J. Hooker, Simon M. Hopps, Nicholas Hull, Janet Hunt, David Jaroszynski, Dino A. Kempenaars, Mark Kessler, Helmut Knight, Sir Peter L. Knight, Steve Knowles, Adrian Lewis, Ciaran L. S. Lipton, Ken S. Littlechild, Abby Littlechild, John Maggs, Peter Malcolm, Graeme P. A. Mangles, Stuart P. D. Martin, William McKenna, Paul Moore, Richard O. Morrison, Clive Najmudin, Zulfikar Neely, David New, Geoff H. C. Norman, Michael J. Paine, Ted Parker, Anthony W. Penman, Rory R. Pert, Geoff J. Pietraszewski, Chris Randewich, Andrew Rizvi, Nadeem H. Seddon, Nigel Sheng, Zheng-Ming Slater, David Smith, Roland A. Spindloe, Christopher Taylor, Roy Thomas, Gary Tisch, John W. G. Wark, Justin S. Webb, Colin Wiggins, S. Mark Willford, Dave and Winstone, Trevor 2021. A history of high-power laser research and development in the United Kingdom. High Power Laser Science and Engineering, Vol. 9, Issue. ,

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New high-power laser facility PALS—prospects for laser–plasma research

Abstract

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New high-power laser facility PALS—prospects for laser–plasma research

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