Hostname: page-component-cd9895bd7-jn8rn Total loading time: 0 Render date: 2024-12-26T04:18:58.623Z Has data issue: false hasContentIssue false

Towards ultra-intense ultra-short ion beams driven by a multi-PW laser

Published online by Cambridge University Press:  26 July 2019

J. Badziak
Affiliation:
Institute of Plasma Physics and Laser Microfusion, Warsaw, Poland
J. Domański*
Affiliation:
Institute of Plasma Physics and Laser Microfusion, Warsaw, Poland
*
Author for correspondence: J. Domański, Institute of Plasma Physics and Laser Microfusion, Warsaw, Poland. E-mail: jaroslaw.domanski@ifpilm.pl

Abstract

The multi-petawatt (PW) lasers currently being built in Europe as part of the Extreme Light Infrastructure (ELI) project will be capable of generating femtosecond light pulses of ultra-relativistic intensities (~1023–1024 W/cm2) that have been unattainable so far. Such laser pulses can be used for the production of high-energy ion beams with unique features that could be applied in various fields of scientific and technological research. In this paper, the prospect of producing ultra-intense (intensity ≥1020 W/cm2) ultra-short (pico- or femtosecond) high-energy ion beams using multi-PW lasers is outlined. The results of numerical studies on the acceleration of light (carbon) ions, medium-heavy (copper) ions and super-heavy (lead) ions driven by a femtosecond laser pulse of ultra-relativistic intensity, performed with the use of a multi-dimensional (2D3 V) particle-in-cell code, are presented, and the ion acceleration mechanisms and properties of the generated ion beams are discussed. It is shown that both in the case of light ions and in the case of medium-heavy and super-heavy ions, ultra-intense femtosecond multi-GeV ion beams with a beam intensity much higher (by a factor ~102) and ion pulse durations much shorter (by a factor ~104–105) than achievable presently in conventional radio frequency-driven accelerators can be produced at laser intensities of 1023 W/cm2 predicted for the ELI lasers. Such ion beams can open the door to new areas of research in high-energy density physics, nuclear physics and inertial confinement fusion.

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

Allen, M, Patel, PK, MacKinnon, A, Price, D, Wilks, S and Morse, E (2004) Direct experimental evidence of back-surface ion acceleration from laser-irradiated gold foils. Physical Review Letters 93, 265004-1-4.Google Scholar
Ammosov, MV, Delone, NB and Krainov, VP (1986) Tunnel ionization of complex atoms and of atomic ions in an alternating electromagnetic field. Soviet Physics JETP 64, 1191.Google Scholar
Badziak, J (2007) Laser-driven generation of fast particles. Opto-Electronics Review 15, 1.Google Scholar
Badziak, J, Parys, P, Vankov, AB, Wołowski, J and Woryna, E (2001) Generation of fluxes of highly charged ions from a picosecond laser-produced plasma. Applied Physics Letters 79, 2123.Google Scholar
Badziak, J, Głowacz, S, Jabłoński, S, Parys, P, Wołowski, J, Hora, H, Krasa, J, Laska, L and Rochlena, K (2004) Production of ultrahigh ion current densities at skin-layer subrelativistic laser–plasma interaction. Plasma Physics and Controlled Fusion 46, B541B555.Google Scholar
Badziak, J, Jabłoński, S, Parys, P, Rosiński, M, Wołowski, J, Szydłowski, A, Antici, P, Fuchs, J and Mancic, A (2008) Ultraintense proton beams from laser-induced skin-layer ponderomotive acceleration. Journal of Applied Physics 104, 063310.Google Scholar
Badziak, J, Jabłoński, S, Pisarczyk, T, Rączka, P, Krokusky, 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.Google Scholar
Badziak, J, Parys, P, Rosiński, M, Krousky, E, Ullschmied, J and Torrisi, L (2013) Improved generation of ion fluxes by a long pulse using laser-induced cavity pressure acceleration. Applied Physics Letters 103, 124104.Google Scholar
Borghesi, M, Fuchs, J, Bulanov, SV, MacKinnon, AJ, Patel, PK and Roth, M (2006) Fast ion generation by high-intensity laser irradiation of solid targets and applications. Fusion Science and Technology 49, 412.Google Scholar
Braenzel, J, Andreev, AA, Platonov, K, Klingsporn, M, Sandner, W and Schnurer, M (2015) Coulomb-Driven energy boost of heavy ions for laser-plasma acceleration. Physical Review Letters 114, 124801.Google Scholar
Bulanov, SV, Esirkepov, TZ, Khoroshkov, VS, Kuznetsov, AV and Pegoraro, F (2002) Oncological hadrontherapy with laser ion accelerators. Physics Letters A299, 240247.Google Scholar
Bulanov, SS, Esarey, E, Schroeder, CB, Bulanov, SV, Esirkepov, TZ, Kondo, M and Leemans, WP (2016) Radiation pressure acceleration: The factors limiting maximum attainable ion energy. Physics of Plasmas 23, 056703.Google Scholar
Bychenkov, VY and Kovaliev, VF (2005) Coulomb explosion in a cluster plasma. Plasma Physics Reports 31, 178183.Google Scholar
Capdessus, R and McKenna, P (2015) Influence of radiation force on ultraintense laser-driven ion acceleration. Physical Review E 91, 053105.Google Scholar
Chen, M, Cormier-Michel, E, Geddes, CGR, Bruhwiler, DL, Yu, LL, Esarey, E, Schroeder, CB and Leemans, WP (2013) Numerical modelling of laser tunnelling ionization in explicit particle-in-cell codes. Journal of Computational Physics 236, 220.Google Scholar
Clark, EL, Krushelnick, K, Zepf, M, Beg, FN, Tatarakis, M, Machacek, A, Santala, MIK, Watts, I, Norreys, PA and Dangor, AE (2000) Energetic heavy-ion and proton generation from ultraintense laser-plasma interactions with solids. Physical Review Letters 85, 16541657.Google Scholar
Cowan, TE, Fuchs, J, Ruhl, H, Kemp, A, Audebert, P, Roth, M, Stephens, R, Barton, I, Blazevic, A, Brambrink, E, Fernandez, J, Gauthier, JC, Geissel, M, Hegelich, M, Kaae, J, Karsch, S, Le Sage, GP, Letzring, S, Manclossi, M, Meyroneinc, S, Newkirk, A, Pepin, H and Renard-LeGall-oudec, N (2004) Ultralow emittance, multi-MeV proton beams from a laser virtual-cathode plasma accelerator. Physical Review Letters 92, 204801-1-4.Google Scholar
Daido, H, Nishiuchi, M and Pirozhkov, AS (2012) Review of laser-driven ion sources and their applications. Reports on Progress in Physics 75, 056401.Google Scholar
Davis, J, Petrov, GM and Mehlhorn, TA (2011) Generation of laser-driven light ions suitable for fast ignition of fusion targets. Plasma Physics and Controlled Fusion 53, 045013.Google Scholar
Domański, J and Badziak, J (2018) Ultra-intense femtosecond super-heavy ion beams driven by a multi-PW laser. Physics Letters A 382, 34123417.Google Scholar
Domański, J, Badziak, J and Jabłoński, S (2017) Generation of proton beams from two-species targets irradiated by a femtosecond laser pulse of ultra-relativistic intensity. Laser and Particle Beams 35, 286293.Google Scholar
Domański, J, Badziak, J and Marchwiany, M (2018) Laser-driven acceleration of heavy ions at ultra-relativistic laser intensity. Laser and Particle Beams 36, 507.Google Scholar
Drake, R.P. (2006). High-Energy-Density Physics, Berlin, Hidelberg: Springer-Verlag.Google Scholar
Esirkepov, T, Bingham, R, Bulanov, S, Honda, T, Nishihara, K and Pegoraro, F (2000) Coulomb explosion of a cluster irradiated by a high intensity laser pulse. Laser and Particle Beams 18, 503.Google Scholar
Esirkepov, T, Borghesi, M, Bulanov, SV, Mourou, G and Tajima, T (2004) Highly efficient relativistic-ion generation in the laser-piston regime. Physical Review Letters 92, 175003.Google Scholar
Fernandez, JC, Albright, BJ, Beg, FN, Foord, ME, Hegelich, BM, Honrubia, JJ, Roth, M, Stephens, RB and Yin, L (2014) Fast ignition with laser-driven proton and ion beams. Nuclear Fusion 54, 054006.Google Scholar
Fritzer, S, Malka, V, Grillon, G, Rousseau, JP, Burgy, F, Lefebvre, E, d'Humieres, E, McKenna, P and Ledingham, KWD (2003) Proton beams generated with high-intensity laser: applications to medical isotope production. Applied Physics Letters 83, 30393041.Google Scholar
Fuchs, J, Antici, P, d'Humie'res, E, Lefebvre, E, Borghesi, M, Brambrink, E, Cecchetti, CA, Kaluza, M, Malka, V, Manclossi, M, Meyroneinc, S, Mora, P, Schreiber, J, Toncian, T, Pepinand, H and Audebert, P (2006) Laser-driven proton scaling laws and new paths towards energy increase. Nature Physics 2, 4854.Google Scholar
Głowacz, S, Hora, H, Badziak, J, Jabłoński, S, Cang, Y and Osman, F (2006) Analytical description of rippling effect and ion acceleration in plasma produced by a short laser pulse. Laser and Particle Beams 24, 1525.Google Scholar
Grech, M, Skupin, S, Diaw, A, Schlegel, T and Tikhonchuk, VT (2011) Energy distribution in radiation pressure accelerated ion beams. New Journal of Physics 13, 123003.Google Scholar
Higginson, A, Gray, RJ, King, M, Dance, RJ, Williamson, SDR, Butler, NMH, Wilson, R, Capdessus, R, Armstrong, C, Green, JS, Hawkes, SJ, Martin, P, Wei, WQ, Mirfayzi, SR, Yuan, XH, Kar, S, Borghesi, M, Clarke, RJ, Neely, D and McKenna, P (2018) Near- 100 MeV protons via a laser-driven transparency-enhanced hybrid acceleration scheme. Nature Communications 9, 724.Google Scholar
Hoffmann, DHH, Fortov, VE, Kuster, M, Mintsev, V, Sharkov, BY, Tahir, NA, Udrea, S, Varentsov, D and Weyrich, K (2009) High energy density physics generated by intense heavy ion beams. Astrophysics and Space Science 322, 167.Google Scholar
Jung, D, Yin, L, Albright, BJ, Gautier, DC, Hörlein, R, Kiefer, D, Henig, A, Johnson, R, Letzring, S, Palaniyappan, S, Shah, R, Shimada, T, Yan, XQ, Bowers, KJ, Tajima, T, Fernández, JC, Habs, D and Hegelich, BM (2011) Monoenergetic ion beam generation by driving ion solitary waves with circularly polarized laser light. Physical Review Letters 107, 115002.Google Scholar
Klimo, O, Psikal, J, Limpouch, J and Tikhonchuk, VT (2008) Monoenergetic ion beams from ultrathin foils irradiated by ultrahigh-contrast circularly polarized laser pulses. Physical Review Special Topics – Accelerators And Beams 11, 031301.Google Scholar
Koenig, M, Benuzzi-Mounaix, A, Ravasio, A, Vinci, T, Ozaki, N, Lepape, S, Batani, D, Huser, G, Hall, T, Hicks, D, MacKinnon, A, Patel, P, Park, HS, Boehly, T, Borghesi, M, Kar, S and Romagnani, L (2005) Progress in the study of warm dense matter. Plasma Physics and Controlled Fusion 47, B441B449.Google Scholar
Kramida, A., Ralchenko, Yu. and Reader, J. & NIST ASD Team (2018). NIST atomic spectra database (ver. 5.5.2), Available at http://physics.nist.gov/asd, National Institute of Standards and Technology, Gaithersburg, MD, USA.Google Scholar
Krushelnik, K, Clark, EL, Allot, R, Beg, FN, Danson, CN and Machacek, A (2000) Ultra-high intensity laser-produced plasmas as a compact heavy ion injection source. IEEE Transactions on Plasma Science 28, 11841189.Google Scholar
Ledingham, KWD and Galster, W (2010) Laser-driven particle and photon beams and some applications. New Journal of Physics 12, 045005.Google Scholar
Li, J, Arefiev, AV, Bulanov, SS, Kawahito, D, Bailly-Grandvaux, M, Petrov, GM, McGuffey, C and Beg, FN (2019) Ionization injection of highly-charged copper ions for laser-driven acceleration from ultra-thin foils. Scientific Reports 9, 666.Google Scholar
Macchi, A, Cattani, F, Liseykina, TV and Cornalti, F (2005) Laser acceleration of ion bunches at the front surface of over-dense plasmas. Physical Review Letters 94, 165003.Google Scholar
Macchi, A, Borghesi, M and Passoni, M (2013) Ion acceleration by superintense laser-plasma interaction. Reviews of Modern Physics 85, 751.Google Scholar
MacKinnon, AJ, Sentoku, Y, Patel, PK, Andersen, C, Snavely, R and Freeman, RR (2002) Enhancement of proton acceleration by hot-electron recirculation in thin foils irradiated by ultraintense laser pulses. Physical Review Letters 88, 215006-1-4.Google Scholar
McKenna, P, Ledingham, KWD, Yang, JM, Robson, L, McCanny, T, Shimizu, S, Clarke, RJ, Neely, D, Spohr, K, Chapman, R, Singhal, RP, Krushelnick, K, Wei, MS and Norreys, PA (2004) Characterization of proton and heavier ion acceleration in ultrahigh-intensity laser interactions with heated target foils. Physical Review E 70, 036405.Google Scholar
Negoita, F, Roth, M, Thirolf, PG, Tudisco, S, Hannachi, F, Moustaizis, S, Pomerantz, I, McKenna, P, Fuchs, J, Sphor, K, Acbas, G, Anzalone, A, Audebert, P, Balascuta, S, Cappuzzello, F, Cernaianu, MO, Chen, S, Dancus, I, Freeman, R, Geissel, H, Ghenuche, P, Gizzi, L, Gobet, F, Gosselin, G, Gugiu, M, Higginson, D, D'Humieres, E, Ivan, C, Jaroszynski, D, Kar, S, Lamia, L, Leca, V, Neagu, L, Lanzalone, G, Meot, V, Mirfayzi, SR, Mitu, IO, Morel, P, Murphy, C, Petcu, C, Petrascu, H, Petrone, C, Raczka, P, Risca, M, Rotaru, F, Santos, JJ, Schumacher, D, Stutman, D, Tarisien, M, Tataru, M, Tatulea, B, Turcu, ICE, Versteegen, M, Ursescu, D, Gales, S and Zamfir, NV (2016) Laser-driven nuclear physics at ELI_NP. Romanian Reports in Physics 68, (Suppl.), S37S144. http://www.eli-laser.eu.Google Scholar
Nishiuchi, M, Sakaki, H, Esirkepov, TZ, Nishio, K, Pikuz, TA, Faenov, AY, Skobelev, IY, Orlandi, R, Sako, H, Pirozhkov, AS, Matsukawa, K, Sagisaka, A, Ogura, K, Kanasaki, M, Kiriyama, H, Fukuda, Y, Koura, H, Kando, M, Yamauchi, T, Watanabe, Y, Bulanov, SV, Kondo, K, Imai, K and Nagamiya, S (2015) Acceleration of highly charged GeV Fe ions from a low-Z substrate by intense femtosecond laser. Physics of Plasmas 22, 033107.Google Scholar
Paul, H. (2012) The Stopping Power of Matter for Positive Ions, Modern Practices in Radiation Therapy and Natanasabapathi, G (ed.), ISBN: 978-953-51-0427-8, London: InTech, p. 124. Available at: http://www.intechopen.com/books/modern-practices-in-radiation-therapy/the-stopping-power-of-matter-forpositive-ions.Google Scholar
Petrov, GM, McGuffey, C, Thomas, AGR, Krushelnick, K and Beg, FN (2016) Generation of heavy ion beams using femtosecond laser pulses in the target normal sheath acceleration and radiation pressure acceleration regimes. Physics of Plasmas 23, 063108.Google Scholar
Petrov, GM, McGuffey, C, Thomas, AGR, Krushelnick, K and Beg, FN (2017) Heavy ion acceleration in the radiation pressure acceleration and breakout afterburner regimes. Plasma Physics and Controlled Fusion 59, 075003.Google Scholar
Popov, VS (2004) Tunnel and multiphoton ionization of atoms and ions in a strong laser field(Keldysh theory). Physics-Uspekhi 47, 855.Google Scholar
Qiao, B, Shen, XF, He, H, Xie, Y, Zhang, H, Zhou, CT, Zhu, SP and He, XT (2019) Revisit on ion acceleration mechanisms in solid targets driven by intense laser pulses. Plasma Physics and Controlled Fusion 61, 014039.Google Scholar
Robinson, APL, Zepf, M, Kar, S, Evans, RG and Bellei, C (2008) Radiation pressure acceleration of thin foil with circular polarized laser pulse. New Journal of Physics 10, 013021.Google Scholar
Roth, M, Cowan, TE, Key, MH, Hatchett, SP, Brown, C, Fountain, W, Johnson, J, Pennington, DM, Snavely, RA, Wilks, SC, Yasuike, K, Ruhl, H, Pegoraro, F, Bulanov, SV, Campbell, EM, Perry, MD and Powell, H (2001) Fast ignition by intense laser-accelerated proton beams. Physical Review Letters 86, 436439.Google Scholar
Sharkov, BY, Hoffmann, DHH, Golubev, AA and Zhao, Y (2016) High energy density physics with intense ion beams. Matter and Radiation at Extremes 1, 28.Google Scholar
Silva, LO, Marti, M, Davies, JR and Fonseca, RA (2004) Proton shock acceleration in laser-plasma interactions. Physical Review Letters 92, 015002.Google Scholar
Snavely, RA, Key, MH, Hatchett, SP, Cowan, TE, Roth, M, Phillips, TW, Singh, MA, Wilks, SC, Offenberger, A, Pennington, DM, Yasuike, K, Langton, AB, Lasinski, BF, Johnson, J, Perry, MD and Campbell, EM (2000) Intense high-energy proton beams from petawatt-laser irradiation of solids. Physical Review Letters 85, 29452948.Google Scholar
Tamburini, M, Pegoraro, F, Di Piazza, A, Keitel, CN and Macchi, A (2010) Radiation reaction effects on radiation pressure acceleration. New Journal of Physics 12, 123005.Google Scholar
Torrisi, L, Gammino, S, Mezzasalma, AM, Badziak, J, Parys, P, Wołowski, J, Woryna, E, Krasa, J, Laska, L, Pfeifer, M, Rohlena, K and Boody, FP (2003) Implantation of ions produced by the use of high power iodine laser. Applied Surface Science 217, 319331.Google Scholar
Torrisi, L, Gammino, S, Ando, L, Laska, L, Krasa, J, Rohlena, K, Ullschmied, J, Wołowski, J, Badziak, J and Parys, P (2006) Equivalent ion temperature in Ta plasma produced by high energy laser ablation. Journal of Applied Physics 99, 083301.Google Scholar
Wilks, SC, Langdon, AB, Cowan, TE, Roth, M, Singh, M, Hatchett, S, Key, MH, Pennington, D, MacKinnon, A and Snavely, RA (2001) Energetic proton generation in ultra-intense laser-solid interactions. Physics of Plasmas 8, 542.Google Scholar
Wołowski, J, Badziak, J, Czarnecka, A, Parys, P, Pisarek, M, Rosinski, M, Turan, R and Yerci, S (2007) Application of pulsed laser deposition and laser-induced ion implantation for formation of semiconductor nano-crystallites. Laser and Particle Beams 25, 6569.Google Scholar
Wu, D, Qiao, B, McGuffey, C, He, XT and Beg, FN (2014) Generation of high-energy mono-energetic heavy ion beams by radiation pressure acceleration of ultra-intense laser pulses. Physics of Plasmas 21, 123118.Google Scholar
Xu, Y, Wang, J, Qi, X, Li, M, Xing, Y, Yang, L and Zhu, W (2017) Plasma block acceleration via double targets driven by an ultraintense circularly polarized laser pulse. Physics of Plasmas 24, 033108.Google Scholar
Yin, L, Albright, BJ, Hegelich, BM and Fernandez, JC (2006) GeV laser ion acceleration from ultrathin targets: the laser breakout afterburner. Laser and Particle Beams 24, 291298.Google Scholar
Yin, L, Albright, BJ, Hegelich, BM, Browers, KJ, Flippo, KA, Kwan, TJT and Fernandez, JC (2007) Monoenergetic and GeV ion acceleration from the laser breakout afterburner using ultrathin targets. Physics of Plasmas 14, 056706.Google Scholar
Yin, L, Albright, BJ, Jung, D, Bowers, KJ, Shah, RC, Palaniyappan, S, Fernández, JC and Hegelich, BM (2011) Mono-energetic ion beam acceleration in solitary waves during relativistic transparency using high-contrast circularly polarized short-pulse laser and nanoscale targets. Physics of Plasmas 18, 053103.Google Scholar
Zheng, FL, Wang, HY, Yan, XQ, Tajina, T, Yu, MY and He, XT (2012) Sub-TeV proton beam generation by ultra-intense irradiation of foil-and-gas target. Physics of Plasmas 19, 023111.Google Scholar