Hostname: page-component-cd9895bd7-hc48f Total loading time: 0 Render date: 2024-12-27T06:54:21.545Z Has data issue: false hasContentIssue false

Time-resolved studies of low-temperature, EUV-induced plasmas: EUV emission in selected spectral ranges

Published online by Cambridge University Press:  20 November 2019

A. Bartnik*
Affiliation:
Institute of Optoelectronics, Military University of Technology, Warsaw, Poland
H. Fiedorowicz
Affiliation:
Institute of Optoelectronics, Military University of Technology, Warsaw, Poland
P. Wachulak
Affiliation:
Institute of Optoelectronics, Military University of Technology, Warsaw, Poland
T. Fok
Affiliation:
Institute of Optoelectronics, Military University of Technology, Warsaw, Poland
*
Author for correspondence: A. Bartnik, Institute of Optoelectronics, Military University of Technology, Warsaw, Poland. E-mail: andrzej.bartnik@wat.edu.pl

Abstract

Interaction of extreme ultraviolet (EUV) pulses of high intensity with gases results in the creation of non-thermalized plasmas. Energies of the driving photons and photoelectrons are sufficient for creation of excited states, followed by emission of the EUV photons. In most cases, decay times of these states are short comparing to the driving EUV pulse. It means that just after stopping of the driving pulse, the EUV emission corresponding to the excited states should also stop. From our earlier measurements in the optical range, however, it can be concluded that lifetimes of such plasmas exceed a time duration of the driving pulse even two orders of magnitude. Hence, it can be expected that the time duration of the EUV emission can be also significantly longer than the irradiation time. In this work, EUV-induced, low-temperature helium (He), krypton, and xenon plasmas were investigated. EUV emission from these plasmas was studied, using a specially prepared detection system, allowing for time-resolved measurements, in selected spectral ranges. The detection system was based on a paraboloidal collector and a semiconductor photodiode, sensitive for the EUV photons. For spectral selection, the corresponding filters or multilayer mirrors were employed. In most cases, the time duration of the EUV emission was significantly longer than the driving EUV pulse. In case of He plasmas, the emission corresponding to excited atoms was detected even hundreds of nanoseconds after the irradiation. It was also shown that the corresponding time profiles depended on densities of gases to be ionized.

Type
Research Article
Copyright
Copyright © Cambridge University Press 2019

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Bailey, JE, Cohen, D, Chandler, G, Cuneo, M, Foord, M, Heeter, R, Jobe, D, Lake, P, Liedahl, D, MacFarlane, J, Nash, T, Nielson, D, Smelser, R and Stygar, W (2001) Neon photoionization experiments driven by Z-pinch radiation. Journal of Quantitative Spectroscopy and Radiative Transfer 71, 157.CrossRefGoogle Scholar
Bartlett, PL and Stelbovics, AT (2002) Calculation of electron-impact total-ionization cross sections. Physical Review A 66, 012707.CrossRefGoogle Scholar
Bartnik, A (2015) Laser-plasma extreme ultraviolet and soft X-ray sources based on a double stream gas puff target: interaction of the radiation pulses with matter (Review). Optoelectronics Review 23, 172186.Google Scholar
Bartnik, A, Fiedorowicz, H, Rakowski, R, Szczurek, M, Bijkerk, F, Bruijn, R and Fledderus, H (2001) Soft X−ray emission from a double stream gas puff target irradiated by a nanosecond laser pulse. Proceedings of SPIE 4424, 406409.CrossRefGoogle Scholar
Bartnik, A, Wachulak, P, Fok, T, Węgrzynski, L, Fiedorowicz, H, Skrzeczanowski, W, Pisarczyk, T, Chodukowski, T, Kalinowska, Z, Dudzak, R, Dostal, J, Krousky, E, Skala, J, Ullschmied, J, Hrebicek, J and Medrik, T (2015) Photoionized argon plasmas induced with intense soft x-ray and extreme ultraviolet pulses. Plasma Physics and Controlled Fusion 58, 014009.CrossRefGoogle Scholar
Bartnik, A, Wachulak, P, Fiedorowicz, H and Skrzeczanowski, W (2016) Kr photoionized plasma induced by intense EUV pulses. Physics of Plasmas 23, 043512.CrossRefGoogle Scholar
Bartnik, A, Skrzeczanowski, W, Wachulak, P, Saber, I, Fiedorowicz, H, Fok, T and Węgrzyński, Ł (2017) Low-temperature photoionized plasmas induced in Xe gas using an EUV source driven by nanosecond laser pulses. Laser and Particle Beams 35, 4247.CrossRefGoogle Scholar
Bredice, F, Raineri, M, Almandos, JR, Gallardo, M and Trigueiros, AG (2000) Weighted oscillator strengths for Kr IV spectrum. Journal of Quantitative Spectroscopy and Radiative Transfer 65, 805819.CrossRefGoogle Scholar
Cohen, DH, MacFarlane, JJ, Bailey, JE and Liedahl, DA (2003) X-ray spectral diagnostics of neon photoionization experiments on the Z-machine. Review of Scientific Instruments 74, 1962.CrossRefGoogle Scholar
Drescher, M, Hentschel, M, Kienberger, R, Uiberacker, M, Yakovlev, V, Scrinzi, A, Westerwalbesloh, T, Kleineberg, U, Heinzmann, U and Krausz, F (2002) Time-resolved atomic inner-shell spectroscopy. Nature 419, 803807.CrossRefGoogle ScholarPubMed
Falcon, RE, Rochau, GA, Bailey, JE, Ellis, JL, Carlson, AL, Gomez, TA, Montgomery, MH, Winget, DE, Chen, EY, Gomez, MR and Nash, TJ (2013) An experimental platform for creating white dwarf photospheres in the laboratory. High Energy Density Physics 9, 8290.CrossRefGoogle Scholar
Fiedorowicz, H, Bartnik, A, Daido, H, Choi, IW, Suzuki, M and Yamagami, S (2000) Strong extreme ultraviolet emission from a double−stream xenon/helium gas puff target irradiated with a Nd:YAG laser. Optics Communications 184, 161167.CrossRefGoogle Scholar
Fujioka, S, Takabe, H, Yamamoto, N, Salzmann, D, Wang, F, Nishimura, H, Li, Y, Dong, Q, Wang, S, Zhang, Y, Rhee, Y, Lee, Y, Han, J, Tanabe, M, Fujiwara, T, Nakabayashi, Y, Zhao, G, Zhang, J and Mima, K (2009) X-ray astronomy in the laboratory with a miniature compact object produced by laser-driven implosion. Nature Physics 5, 821825.CrossRefGoogle Scholar
Gong, T, Hao, L, Li, Z, Yang, D, Li, S, Li, X, Guo, L, Zou, S, Liu, Y, Jiang, X, Peng, X, Xu, T, Liu, X, Li, Y, Zheng, C, Cai, H, Liu, Z, Zheng, J, Wang, Z, Li, Q, Li, P, Zhang, R, Zhang, Y, Wang, F, Wang, D, Wang, F, Liu, S, Yang, J, Jiang, S, Zhang, B and Ding, Y (2019) Recent research progress of laser plasma interactions in Shenguang laser facilities. Matter and Radiation at Extremes 4, 055202.CrossRefGoogle Scholar
Kapteyn, HC and Falcone, RW (1988) Auger-pumped short-wavelength lasers in xenon and krypton. Physical Review A 37, 20332038.CrossRefGoogle ScholarPubMed
Kapteyn, HC, Lee, RW and Falcone, RW (1986) Observation of a short-wavelength laser pumped by Auger decay. Physical Review Letters 57, 29392942CrossRefGoogle ScholarPubMed
Kelly, RL (1987) Atomic and ionic spectrum lines below 2000 angstroms: hydrogen through krypton part I (H-Cr). Journal of Physical and Chemical Reference Data 16, 1649.Google Scholar
Könneckea, R, Follath, R, Pontius, N, Schlappa, J, Eggenstein, F, Zeschke, T, Bischoff, P, Schmidt, J-S, Nolla, T, Trabanta, C, Schreck, S, Wernet, P, Eisebitt, S, Senf, F, Schüßler-Langeheine, C, Erko, A and Föhlisch, A (2013) The confocal plane grating spectrometer at BESSY II. Journal of Electron Spectroscopy and Related Phenomena 188, 133139.CrossRefGoogle Scholar
Palaudoux, J, Lablanquie, P, Andric, L, Ito, K, Shigemasa, E, Eland, JHD, Jonauskas, V, Kucas, S, Karazija, R and Penent, F (2010) Multielectron spectroscopy: Auger decays of the krypton 3d hole. Physical Review A 82, 043419CrossRefGoogle Scholar
Pequignot, D, Petitjean, P and Boisson, C (1991) Total and effective recombination coefficiets. Astronomy & Astrophysics 251, 680688.Google Scholar
Raineri, M, Almandos, JGR, Bredice, F, Gallardo, M, Trigueiros, AG and Pettersson, S-G (1998) Weighted oscillator strengths for Kr III spectrum. Journal of Quantitative Spectroscopy and Radiative Transfer 60, 2542.CrossRefGoogle Scholar
Raineri, M, Lagorio, C, Padilla, S, Gallardo, M and Almandos, JR (2008) Weighted oscillator strengths for the Xe IV spectrum. Journal of Quantitative Spectroscopy and Radiative Transfer 94, 140159.Google Scholar
Rakowski, R, Bartnik, A, Fiedorowicz, H, de Gaufridy de Dortan, F, Jarocki, R, Kostecki, J, Mikołajczyk, J, Ryc, L, Szczurek, M and Wachulak, P (2010) Characterization and optimization of the laser-produced plasma EUV source at 13.5 nm based on a double-stream Xe/He gas puff target. Applied Physics B 101, 773.CrossRefGoogle Scholar
Saloman, EB (2004) Energy levels and observed spectral lines of xenon, XeI through XeLIV. Journal of Physical and Chemical Reference Data 33, 765921.CrossRefGoogle Scholar
Saloman, EB (2007) Energy levels and observed spectral lines of krypton, Kr I through Kr XXXVI. Journal of Physical and Chemical Reference Data 36, 215386.CrossRefGoogle Scholar
Sampaio, JM, Madeira, TI, Guerra, M, Parente, F, Santos, JP, Indelicato, P and Marques, JP (2015) Dirac-Fock calculations of K-, L-, and M-shell fluorescence and Coster-Kronig yields for Ne, Ar, Kr, Xe, Rn, and Uuo. Physical Review A 91, 052507.CrossRefGoogle Scholar
Sher, MH, Macklin, JJ, Young, JF and Harris, SE (1987) Saturation of the Xe III 109-nm laser using traveling-wave laser-produced-plasma excitation. Optics Letters 12, 891893.CrossRefGoogle ScholarPubMed
Spitzer, L Jr (1962) Physics of Fully Ionized Gases. New York: Interscience Publisher, Inc.Google Scholar
van der Horst, RM, Beckers, J, Nijdam, S and Kroesen, GMW (2014) Exploring the temporally resolved electron density evolution in extreme ultra-violet induced plasmas. Journal of Physics D: Applied Physics 47, 302001.CrossRefGoogle Scholar
van der Horst, RM, Beckers, J, Osorio, EA, Astakhov, DI, Goedheer, WJ, Lee, CJ, Ivanov, VV, Krivtsum, VM, Koshelev, KN, Lopaev, DV, Bijkerk, F and Banine, VY (2016) Exploring the electron density in plasma induced by EUV radiation: I. Experimental study in hydrogen. Journal of Physics D: Applied Physics 49, 145203.CrossRefGoogle Scholar
Viefhaus, J, Braune, M, Korica, S, Reinkoster, A, Rolles, D and Becker, U (2005) Auger cascades versus direct double Auger: relaxation processes following photoionization of the Kr 3d and Xe 4d, 3d inner shells. Journal of Physics B: Atomic, Molecular and Optical Physics 38, 38853903.CrossRefGoogle Scholar
Wei, HG, Shi, JR, Zhao, G, Zhang, Y, Dong, QL, Li, YT, Wang, SJ, Zhang, J, Liang, ZT, Zhang, JY, Wen, TS, Zhang, WH, Hu, X, Liu, SY, Ding, YK, Zhang, L, Tang, YJ, Zhang, BH, Zheng, ZJ, Nishimura, H, Fujioka, S, Wang, FL and Takabe, H (2008) Opacity studies of silicon in radiatively heated plasmas. The Astrophysical Journal 683, 577583.CrossRefGoogle Scholar