Hostname: page-component-586b7cd67f-vdxz6 Total loading time: 0 Render date: 2024-11-24T13:32:32.709Z Has data issue: false hasContentIssue false

Efficient acceleration of a dense plasma projectile to hyper velocities in the laser-induced cavity pressure acceleration scheme

Published online by Cambridge University Press:  25 January 2018

J. Badziak*
Affiliation:
Institute of Plasma Physics and Laser Microfusion, 01-497, Warsaw, Poland
E. Krousky
Affiliation:
Institute of Plasma Physics ASCR, 182 00, Prague, Czech Republic Institute of Physic ASCR s, 182 21, Prague, Czech Republic
J. Marczak
Affiliation:
Military University of Technology in Warsaw, 01-476, Warsaw, Poland
P. Parys
Affiliation:
Institute of Plasma Physics and Laser Microfusion, 01-497, Warsaw, Poland
T. Pisarczyk
Affiliation:
Institute of Plasma Physics and Laser Microfusion, 01-497, Warsaw, Poland
M. Rosiński
Affiliation:
Institute of Plasma Physics and Laser Microfusion, 01-497, Warsaw, Poland
A. Sarzynski
Affiliation:
Military University of Technology in Warsaw, 01-476, Warsaw, Poland
T. Chodukowski
Affiliation:
Institute of Plasma Physics and Laser Microfusion, 01-497, Warsaw, Poland
J. Dostal
Affiliation:
Institute of Plasma Physics ASCR, 182 00, Prague, Czech Republic Institute of Physic ASCR s, 182 21, Prague, Czech Republic
R. Dudzak
Affiliation:
Institute of Plasma Physics ASCR, 182 00, Prague, Czech Republic
Z. Kalinowska
Affiliation:
Institute of Plasma Physics and Laser Microfusion, 01-497, Warsaw, Poland
M. Kucharik
Affiliation:
Czech Technical University, FNSPE, 166 36, Prague, Czech Republic
R. Liska
Affiliation:
Czech Technical University, FNSPE, 166 36, Prague, Czech Republic
M. Pfeifer
Affiliation:
Institute of Plasma Physics ASCR, 182 00, Prague, Czech Republic Institute of Physic ASCR s, 182 21, Prague, Czech Republic
J. Ullschmied
Affiliation:
Institute of Plasma Physics ASCR, 182 00, Prague, Czech Republic Institute of Physic ASCR s, 182 21, Prague, Czech Republic
A. Zaraś-Szydłowska
Affiliation:
Institute of Plasma Physics and Laser Microfusion, 01-497, Warsaw, Poland
*
Author for correspondence: J. Badziak, Institute of Plasma Physics and Laser Microfusion, 01-497, Warsaw, Poland, E-mail: [email protected]

Abstract

The experimental study of the plasma projectile acceleration in the laser-induced cavity pressure acceleration (LICPA) scheme is reported. In the experiment performed at the kilojoule PALS laser facility, the parameters of the projectile were measured using interferometry, a streak camera and ion diagnostics, and the measurements were supported by two-dimensional hydrodynamic simulations. It is shown that in the LICPA accelerator with a 200-J laser driver, a 4-μg gold plasma projectile is accelerated to the velocity of 140 km/s with the energetic acceleration efficiency of 15–19% which is significantly higher than those achieved with the commonly used ablative acceleration and the highest among the ones measured so far for any projectiles accelerated to the velocities ≥100 km/s. This achievement opens the possibility of creation and investigation of high-energy-density matter states with the use of moderate-energy lasers and may also have an impact on the development of the impact ignition approach to inertial confinement fusion.

Type
Research Article
Copyright
Copyright © Cambridge University Press 2018 

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

Atzeni, S and Meyer-ter-Vehn, J (2004) The Physics of Inertial Fusion. Oxford: Clarendon.CrossRefGoogle Scholar
Azechi, H, Sakaiya, T, Watari, T, Karasik, M, Saito, H, Ohtani, K, Takeda, K, Hosoda, H, Shiraga, H, Nakai, M, Shigemori, K, Fujioka, S, Murakami, M, Nagatomo, H, Johzaki, T, Gardner, J, Colombant, DG, Bates, JW, Velikovich, AL, Aglitskiy, Y, Weaver, J, Obenschain, S, Eliezer, S, Kodama, R, Norimatsu, T, Fujita, H, Mima, K and Kan, H (2009) Experimental evidence of impact ignition: 100-fold increase of neutron yield by impactor collision. Physical Review Letters 102, 235002.CrossRefGoogle ScholarPubMed
Badziak, J and Jabłoński, S (2011) Acceleration of a solid –density plasma projectile to ultrahigh velocities by a short-pulse ultraviolet laser. Applied Physics Letters 99, 071502.CrossRefGoogle Scholar
Badziak, J, Kasperczuk, A, Parys, P, Pisarczyk, T, Rosiński, M, Ryć, L, Wołowski, J, Jabłoński, S, Suchańska, R, Krousky, E, Láska, L, Mašek, K, Pfeifer, M, Ullschmied, J, Dareshwar, LJ, Földes, I, Torrisi, L and Pisarczyk, P (2007) Production of high-current heavy ion jets at the short-wavelength subnanonosecond laser-solid interaction. Applied Physics Letters 91, 081502.CrossRefGoogle Scholar
Badziak, J, Borodziuk, S, Pisarczyk, T, Chodukowski, T, Krousky, E, Masek, J, Skala, J, Ullschmied, J and Rhee, Y-J (2010) Highly efficient acceleration and collimation of high-density plasma using laser-induced cavity pressure. Applied Physics Letters 96, 251502.CrossRefGoogle Scholar
Badziak, J, Jabłoński, S, Pisarczyk, T, Rączka, P, Krousky, E, Liska, R, Kucharik, M, Chodukowski, T, Kalinowska, Z, Parys, P, Rosiński, M, Borodziuk, S and Ullschmied, J (2012) Highly efficient accelerator of dense matter using laser-induced cavity pressure acceleration. Physics of Plasmas 19, 053105.CrossRefGoogle Scholar
Badziak, J, Krousky, E, Kucharik, M and Liska, R (2016) The LICPA-driven collider – a novel efficient tool for the production of ultra-high pressures in condensed media. Journal of Instrumentation 11, C03043.CrossRefGoogle Scholar
Cauble, R, Phillion, DW, Hoover, TJ, Holmes, NC, Kilkenny, JD and Lee, RW (1993) Demonstration of 0.75 Gbar planar shocks in X-ray driven colliding foils. Physical Review Letters 70, 21022105.CrossRefGoogle ScholarPubMed
Drake, RP (2006) High-Energy-Density Physics. Berlin: Springer.CrossRefGoogle Scholar
Frantaduono, DE, Smith, RF, Boehly, TR, Eggert, JH, Braun, DG and Collins, GW (2012) Plasma-accelerated flyer-plates for equation of state studies. The Review of Scientific Instruments 83, 073504.CrossRefGoogle Scholar
Friichtenicht, JF and Becker, DG (1971) Measurements of the ionization probability of Cu and LaB6 simulated micrometeors. Astrophysical Journal 166, 717724.CrossRefGoogle Scholar
Hurricane, OA, Callahan, DA, Casey, DT, Celliers, PM, Cerjan, C, Dewald, EL, Dittrich, TR, Döppner, T, Hinkel, DE, Berzak, LF, Hopkins, JL, Kline, S, Le Pape, TM, MacPhee, AG, Milovich, JL, Pak, A, Park, H-S, Patel, PK, Remington, BA, Salmonson, JD, Springer, PT and Tommasini, R (2014) Fuel gain exceeding unity in an inertially confined fusion implosion. Nature 506, 343348.CrossRefGoogle Scholar
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 8, 2495.CrossRefGoogle Scholar
Kapin, T, Kucharik, M, Limpouch, J, Liska, R and Vachal, P (2008) Arbitrary Lagrangian Eulerian method for laser plasma simulations. International Journal for Numerical Methods in Fluids 56, 13371342.CrossRefGoogle Scholar
Karasik, M, Weaver, JL, Aglitskiy, Y, Watari, T, Arikawa, Y, Sakaiya, T, Oh, J, Velikovich, AL, Zalesak, ST, Bates, JW, Obenschain, SP, Schmitt, AJ, Murakami, M and Azechi, H (2010) Acceleration to high velocities and heating by impact using Nike KrF laser. Physics of Plasmas 17, 056317.CrossRefGoogle Scholar
Kasperczuk, A and Pisarczyk, T (2001) Application of automated interferometric system for investigation of the behaviour of laser produced plasma in strong external magnetic field. Optica Applicata 31, 571597.Google Scholar
Lemke, RW, Knudson, MD, Bliss, DE, Cochrane, K, Davis, J-P, Giunta, AA, Harjes, HC and Slutz, SA (2005) Magnetically accelerated, ultrahigh velocity flyer plates for shock wave experiments. Journal of Applied Physics 98, 073530.CrossRefGoogle Scholar
Liska, R, Kucharik, M, Limpouch, J, Renner, O, Vachal, P, Bednarik and Velechovsky, L (2011) ALE method for simulations of laser-produced plasmas. In Fort, J, Furst, J, Halama, J, Herbin, R and Hubert, F eds. Finite Volumes for Complex Applications VI, Problems & Perspectives, vol. 2, Berlin Heidelberg: Springer-Verlag, pp. 857873.CrossRefGoogle Scholar
Mitchell, AC, Nellis, WJ, Mariorty, JA, Heinle, RA, Holmes, NC, Tipton, RE and Repp, GW (1991) Equation of state of Al, Cu, Mo, and Pb at shock pressures up to 2.4 TPa (24 Mbar). Journal of Applied Physics 69, 29812988.CrossRefGoogle Scholar
More, RM, Warren, KH, Young, DA and Zimmerman, GB (1988) A new quotidian equation of state (QEOS) for hot dense matter. Physics of Fluids 31, 30593078.CrossRefGoogle Scholar
Murakami, M, Nagatomo, H, Johzaki, T, Sakaiya, T, Velikovich, A, Karasik, M, Guskov, S and Zmitrenko, N (2014) Impact ignition as a track to laser fusion. Nuclear Fusion 54, 054007.CrossRefGoogle Scholar
Nellis, WJ (2016) Dynamic compression of materials: Metallization of fluid hydrogen at high pressures. Reports on Progress in Physics 69, 14791580.CrossRefGoogle Scholar
Obenschain, SP, Whitlock, RR, McLean, EA, Ripin, BH, Price, RH, Phillion, DW, Campbell, EM, Rosen, MD and Aurbach, JM (1983) Uniform ablative acceleration of targets by laser irradiation at 1014 W/cm2. Physical Review Letters 50, 4447.CrossRefGoogle Scholar
Ozaki, N, Sasatani, Y, Kishida, K, Nakano, M, Miyanaga, M, Nagai, K, Nishihara, K, Norimatsu, T, Tanaka, KA, Fujimoto, Y, Wakabayashi, K, Hattori, S, Tange, T, Kondo, K, Yoshida, M, Kozu, N, Ishiguchi, M and Takenaka, H (2001) Planar shock wave generated by uniform irradiation from two overlapped partially coherent laser beams. Journal of Applied Physics 89, 25712576.CrossRefGoogle Scholar
Shui, M, Chu, G-B, Xin, J-T, Wu, Y-C, Zhu, B, He, W-H, Xi, T and Gu, Y-Q (2015). Laser-driven flier impact experiments at the SG-III prototype laser facility. Chinese Physics B24, 094701.CrossRefGoogle Scholar
Shui, M, Chu, G, Zhu, B, He, W, Xi, T, Fan, W, Xin, J and Gu, Y (2016). Hypervelocity launching of flyers at the SG-III prototype laser facility. Journal of Applied Physics 119, 035903.CrossRefGoogle Scholar
Thornhill, TH, Chabildas, LC, Reinhart, WD and Davidson, DL (2006) Particle launch to 19 km/s for micro-meteoroid simulation using enhanced three-stage light gas gun. International Journal of Impact Engineering 33, 799811.CrossRefGoogle Scholar
Woryna, E, Parys, P, Wolowski, J and Mróz, W (1996) Corpuscular diagnostics and processing methods applied in investigations of laser-produced plasma as a source of highly ionized ions. Laser and Particle Beams 14, 293321.CrossRefGoogle Scholar
Yu, W, Xu, H, He, F, Yu, MY, Ishiguro, S, Zhang, J and Wong, AY (2005) Direct acceleration of solid-density plasma bunch by ultraintense laser. Physical Review E 72, 046401.CrossRefGoogle ScholarPubMed