Hostname: page-component-78c5997874-s2hrs Total loading time: 0 Render date: 2024-11-10T04:38:06.607Z Has data issue: false hasContentIssue false
  • English
  • Français

Radiation dominated implosion with nano-plasmonics

Published online by Cambridge University Press:  08 June 2018

L.P. Csernai ,
N. Kroo  and
I. Papp
L.P. Csernai*
Affiliation:
Department of Physics and Technology, University of Bergen, Bergen, Norway
N. Kroo
Affiliation:
Hungarian Academy of Sciences, Budapest, Hungary Wigner Research Centre for Physics, Budapest, Hungary
I. Papp
Affiliation:
Department of Physics, Babes-Bolyai University, Cluj, Romania
*
Author for correspondence: L.P. Csernai, Department of Physics and Technology, University of Bergen, Bergen, Norway. E-mail: [email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

Inertial Confinement Fusion is a promising option to provide massive, clean, and affordable energy for mankind in the future. The present status of research and development is hindered by hydrodynamical instabilities occurring at the intense compression of the target fuel by energetic laser beams. A recent patent combines advances in two fields: Detonations in relativistic fluid dynamics (RFD) and radiative energy deposition by plasmonic nano-shells. The initial compression of the target pellet can be decreased, not to reach the Rayleigh–Taylor or other instabilities, and rapid volume ignition can be achieved by a final and more energetic laser pulse, which can be as short as the penetration time of the light across the pellet. The reflectivity of the target can be made negligible as in the present direct drive and indirect drive experiments, and the absorptivity can be increased by one or two orders of magnitude by plasmonic nano-shells embedded in the target fuel. Thus, higher ignition temperature and radiation dominated dynamics can be achieved with the limited initial compression. Here, we propose that a short final light pulse can heat the target so that most of the interior will reach the ignition temperature simultaneously based on the results of RFD. This makes the development of any kind of instability impossible, which would prevent complete ignition of the target.

Keywords

Inertial confinement fusionnano-shellsrelativistic fluid dynamicstime-like detonation
Type
Research Article
Information
Laser and Particle Beams , Volume 36 , Issue 2 , June 2018 , pp. 171 - 178
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

Alam, M and Massoud, Y (2006) A closed-form analytical model for single nanoshells. IEEE Transactions on Nanotechnology 5, 265.Google Scholar
Armesto, N, Dainese, A, d'Enterria, D, Masciocchi, S, Roland, C, Salgado, CA, van Leeuwen, A and Wiedemann, UA (2014) Heavy-ion physics studies for the future circular collider. Nuclear Physics A 931, 1163.Google Scholar
Bargsten, C, Hollinger, R, Capeluto, MG, Kaymak, V, Pukhov, A, Wang, SJ, Rockwood, A, YWang, Y, Keiss, D, Tommasini, R, London, R, Park, J, Busquet, M, Klapisch, M, Shlyaptsev, VN and Rocca, JJ (2017) Energy penetration into arrays of aligned nanowires irradiated with relativistic intensities: scaling to Terabar pressures. Science Advances 3, e1601558.Google Scholar
Benredjem, D, Pain, JC, Gilleron, F, Ferri, S and Calisti, A (2014) Opacity profiles in inertial confinement fusion. Journal of Physics: Conference Series 548, 012009.Google Scholar
Betti, R and Hurricane, OA (2016) Inertial-confinement fusion with lasers. Nature Physics 12, 435.Google Scholar
Boehly, TR, Goncharov, VN, Seka, W, Barrios, MA, Celliers, PM, Hicks, DG, Collins, GW, Hu, SX, Marozas, JA, and Meyerhofer, DD (2011) Velocity and timing of multiple spherically converging shock waves in liquid deuterium. Physical Review Letters 106, 195005.Google Scholar
Chatterjee, R, Frodermann, ES, Heinz, U and Srivastava, DK (2006) Elliptic flow of thermal photons in relativistic nuclear collisions. Physical Review Letters 96, 202302.Google Scholar
Clark, DS, Marinak, MM, Weber, CR, Eder, DC, Haan, SW, Hammel, BA, Hinkel, DE, Jones, OS, Milovich, JL, Patel, PK, Robey, HF, Salmonson, JD, Sepke, SM and Thomas, CA (2015) Radiation hydrodynamics modeling of the highest compression inertial confinement fusion ignition experiment from the National Ignition Campaign. Physics of Plasmas 22, 022703.Google Scholar
Clark, DS, Weber, CR, Milovich, JL, Salmonson, JD, Kritcher, AL, Haan, SW, Hammel, BA, Hinkel, DE, Hurricane, OA, Jones, OS, Marinak, MM, Patel, PK, Robey, HF, Sepke, SM and. Edwards, MJ (2016) Three-dimensional simulations of low foot and high foot implosion experiments on the National Ignition Facility. Physics of Plasmas 23, 056302.Google Scholar
Csernai, LP (1987) Detonation on a time-like front for relativistic systems. Zhurnal Eksperimental'noi i Teoreticheskoi Fiziki 92, 379386.Google Scholar
Csernai, LP (1994) Introduction to Relativistic Heavy Ion Collisions. Cichester, England: John Wiley & Sons.Google Scholar
Csernai, LP and Strottman, DD (2015) Volume ignition via time-like detonation in pellet fusion. Laser and Particle Beams 33, 279282.Google Scholar
Csernai, LP, Kroo, N and Papp, I (2017) Procedure to improve the stability and efficiency of laser-fusion by nano-plasmonics method. Patent # P1700278/3 of the Hungarian Intellectual Property Office.Google Scholar
Csernai, LP, Cheng, Y, Horvat, S, Magas, V, Strottman, D and Zétényi, M (2009) Flow analysis with 3-dim ultra-relativistic hydro. Journal of Physics G 36, 064032.Google Scholar
Floerchinger, S and Wiedemann, UA (2014) Kinetic freeze-out, particle spectra, and harmonic-flow coefficients from mode-by-mode hydrodynamics. Physical Review C 89, 034914.Google Scholar
Frodermann, E, Chatterjee, R and Heinz, U (2007) Evolution of pion HBT radii from RHIC to LHC – Predictions from ideal hydrodynamics. Journal of Physics G 34, 2249.Google Scholar
Glenzer, SH et al. (2011) Demonstration of ignition radiation temperatures in indirect-drive inertial confinement fusion hohlraums. Physical Review Letters 106, 085004.Google Scholar
Haan, SW, Lindl, JD, Callahan, DA, Clark, DS, Salmonson, JD, Hammel, BA, Atherton, LJ, Cook, RC, Edwards, MJ, Glenzer, S, Hamza, AV, Hatchett, SP, Herrmann, MC, Hinkel, DE, Ho, DD, Huang, H, Jones, OS, Kline, J, Kyrala, G, Landen, OL, MacGowan, BJ, Marinak, MM, Meyerhofer, DD, Milovich, JL, Moreno, KA, Moses, EI, Munro, DH, Nikroo, A, Olson, RE, Peterson, K, Pollaine, SM, Ralph, JE, Robey, HF, Spears, BK, Springer, PT, Suter, LJ, Thomas, CA, Town, RP, Vesey, R, Weber, SV, Wilkens, HL and Wilson, DC (2011) Point design targets, specifications, and requirements for the 2010 ignition campaign on the National Ignition Facility. Physics of Plasmas 18, 051001.Google Scholar
Heinz, UW and Kolb, PF (2002) Emission angle dependent pion interferometry at RHIC and beyond. Physics Letters B 542, 216.Google Scholar
Hu, SX, Collins, LA, Goncharov, VN, Boehly, TR, Epstein, R, McCrory, RL and Skupsky, S (2014) First principle opacity table of warm dense deuterium for inertial-confinement-fusion applications. Peer-Reviewed Journal 90, 033111.Google Scholar
James, WD, Hirsch, LR, West, JL, O'Neal, PD and Payne, JD (2007) Application of INAA to the build-up and clearance of gold nanoshells in clinical studies in mice. The Journal of Radioanalytical and Nuclear Chemistry 271, 455459.Google Scholar
Jarrott, LC, Wei, MS, McGuffey, C, Solodov, AA, Theobald, W, Qiao, B, Stoeckl, C, Betti, R, Chen, H, Delettrez, J, Döppner, T, Giraldez, EM, Glebov, VY, Habara, H, Iwawaki, T, Key, MH, Luo, RW, Marshall, FJ, McLean, HS, Mileham, C, Patel, PK, Santos, JJ, Sawada, H, Stephens, RB, Yabuuchi, T and Beg, FN (2016) Visualizing fast electron energy transport into laser-compressed high density fast-ignition targets. Nature Physics 12, 499.Google Scholar
Jones, OS, Cerjan, CJ, Marinak, MM, Milovich, JL, Robey, HF, Springer, PT, Benedetti, LR, Bleuel, DL, Bond, EJ, Bradley, DK, Callahan, DA, Caggiano, JA, Celliers, PM, Clark, DS, Dixit, SM, Doppner, T, Dylla-Spears, RJ, Dzentitis, EG, Farley, DR, Glenn, SM, Glenzer, SH, Haan, SW, Haid, BJ, Haynam, CA, Hicks, DG, Kozioziemski, BJ, LaFortune, KN, Landen, OL, Mapoles, ER, MacKinnon, AJ, McNaney, JM, Meezan, NB, Michel, PA, Moody, JD, Moran, MJ, Munro, DH, Patel, MV, Parham, TG, Sater, JD, Sepke, SM, Spears, BK, Town, RPJ, Weber, SV, Widmann, K, Widmayer, CC, Williams, EA, Atherton, LJ, Edwards, MJ,Lindl, JD, MacGowan, BJ, Suter, LJ, Olson, RE, Herrmann, HW, Kline, JL, Kyrala, GA, Wilson, DC, Frenje, J, Boehly, TR, Glebov, V, Knauer, JP, Nikroo, A, Wilkens, H and Kilkenny, JD (2012) A high-resolution integrated model of the National Ignition Campaign cryogenic layered experiments. Physics of Plasmas 19, 056315.Google Scholar
Kaymak, V, Pukhov, A, Shlyaptsev, VN and Rocca, JJ (2016) Nano-scale ultra-dense Z-pinches formation from laser-irradiated nanowire arrays. Physical Review Letters 117, 035004.Google Scholar
Landen, OL, Benedetti, R, Bleuel, D, Boehly, TR, Bradley, DK, Caggiano, JA, Callahan, DA, Celliers, PM, Cerjan, CJ, Clark, D, Collins, GW, Dewald, EL, Dixit, SN, Doeppner, T, Edgell, D, Eggert, J, Farley, D, Frenje, JA, Glebov, V, Glenn, SM, Glenzer, SH, Haan, SW, Hamza, A, Hammel, BA, Haynam, CA, Hammer, JH, Heeter, RF, Herrmann, HW, Hicks, DG, Hinkel, DE, Izumi, N, Gatu Johnson, M, Jones, OS, Kalantar, DH, Kauffman, RL, Kilkenny, JD, Kline, JL, Knauer, JP, Koch, JA, Kyrala, GA, LaFortune, K, Ma, T, Mackinnon, AJ, Macphee, AJ, Mapoles, E, Milovich, JL, Moody, JD, Meezan, NB, Michel, P, Moore, AS, Munro, DH, Nikroo, A, Olson, RE, Opachich, K, Pak, A, Parham, T, Patel, P, Park, H-S, Petrasso, RP, Ralph, J, Regan, SP, Remington, BA, Rinderknecht, HG, Robey, HF, Rosen, MD, Ross, JS, Salmonson, JD, Sangster, TC, Schneider, MB, Smalyuk, V, Spears, BK, Springer, PT, Suter, LJ, Thomas, CA, Town, RPJ, Weber, SV, Wegner, PJ, Wilson, DC, Widmann, K, Yeamans, C, Zylstra, A, Edwards, MJ, Lindl, JD, Atherton, LJ, Hsing, WW, MacGowan, BJ, Van Wonterghem, BM and Moses, EI (2012) Progress in the indirect-drive National Ignition Campaign. Plasma Physics and Controlled Fusion 54, 124026.Google Scholar
Lee, K-S and El-Sayed, MA (2005) Dependence of the enhanced optical scattering efficiency relative to that of absorption for gold metal nanorods on aspect ratio, size, end-cap shape and medium refractive index. Journal of Physical Chemistry B 109, 2033120338.Google Scholar
Lindl, JD (1998) Inertial Confinement Fusion. New York: Springer.Google Scholar
Lindl, JD, Amendt, P, Berger, RL, Glendinning, SG, Glenzer, SH, Haan, SW, Kauffman, RL, Landen, OL and Suter, LJ (2004) The physics basis for ignition using indirect-drive targets on the National Ignition Facility. Physics of Plasmas 11, 339.Google Scholar
Loo, C, Lin, A, Hirsch, L, Lee, M.-H., Barton, J, Halas, N, West, J and Drezek, R (2004) Nanoshell-Enabled Photonics-Based Imaging and Therapy of Cancer, Technology in Cancer Research & Treatment (ISSN 1533-0346) 3 (1). Schenectady, NY, USA: Adenine Press.Google Scholar
Molnar, E, Molnar, E, Csernai, LP, Magas, VK, Lazar, ZI, Nyiri, A and Tamosiunas, K (2007) Covariant description of kinetic freeze-out through a finite time-like layer. Journal of Physics G 34, 1901.Google Scholar
Nora, R, Theobald, W, Betti, R, Marshall, FJ, Michel, DT, Seka, W, Yaakobi, B, Lafon, M, Stoeckl, C, Delettrez, J, Solodov, AA, Casner, A, Reverdin, C, Ribeyre, X, Vallet, A, Peebles, J, Beg, FN and Wei, MS (2015) Gigabar Spherical Shock Generation on the OMEGA Laser. Physical Review Letters 114, 045001.Google Scholar
Nordlander, P and Prodan, E (2004) Plasmon hybridization in nanoparticles near metallic surfaces. Nano Letters 4, 22092231.Google Scholar
Prodan, E, Radloff, C, Halas, NJ and Nordlander, P (2003) A hybridization model for the plasmon response of Complex Nanostructures. Science 301, 419422.Google Scholar
Reis, VH, Hanrahan, RJ and Levedahl, WK (2016) The big science of stockpile stewardship. Physics Today 69, 46.Google Scholar
Robey, HF, Boehly, TR, Celliers, PM, Eggert, JH, Hicks, D, Smith, RF, Collins, R, Bowers, MW, Krauter, KG, Datte, PS, Munro, DH, Milovich, JL, Jones, OS, Michel, PA, Thomas, CA, Olson, RE, Pollaine, S, Town, RPJ, Haan, S, Callahan, D, Clark, D, Edwards, J, Kline, JL, Dixit, S, Schneider, MB, Dewald, EL, Widmann, K, Moody, JD, Doppner, T, Radousky, HB, Throop, A, Kalantar, D, DiNicola, P, Nikroo, A. Kroll, JJ, Hamza, AV, Horner, JB, Bhandarkar, SD, Dzenitis, E, Alger, E, Giraldez, E, Castro, C, Moreno, K, Haynam, C, LaFortune, KN, Widmayer, C, Shaw, M, Jancaitis, K, Parham, T, Holunga, DM, Walters, CF, Haid, B, Mapoles, ER, Sater, J, Gibson, CR, Malsbury, T, Fair, J, Trummer, D, Coffee, KR, Burr, B, Berzins, LV, Choate, C, Brereton, SJ, Azevedo, S, Chandrasekaran, H, Eder, DC, Masters, ND, Fisher, AC, Sterne, PA, Young, BK, Landen, OL, Van Wonterghem, BM, MacGowan, BJ, Atherton, J, Lindl, JD, Meyerhofer, DD and Moses, E (2012). Shock timing experiments on the National Ignition Facility: initial results and comparison with simulation. Physics of Plasmas 19, 042706.Google Scholar
Sacks, RA and Darling, DH (1987) Direct drive cryogenic ICF capsules employing D-T wetted foam. Nuclear Fusion 27, 447.Google Scholar
Tanabe, K (2016) Plasmonic energy nanofocusing for high-efficiency laser fusion ignition. Japanese Journal of Applied Physics 55, 08RG01.Google Scholar
Zeldovich, YB and Raiser, YP (1966) Physics of Shock Waves and High-Temperature Hydrodynamic Phenomena. Moscow: Nauka.Google Scholar