New scheme to produce aneutronic fusion reactions by laser-accelerated ions

C. Baccou; S. Depierreux; V. Yahia; C. Neuville; C. Goyon; R. De Angelis; F. Consoli; J.E. Ducret; G. Boutoux; J. Rafelski; C. Labaune

doi:10.1017/S0263034615000178

New scheme to produce aneutronic fusion reactions by laser-accelerated ions

Published online by Cambridge University Press: 04 March 2015

C. Baccou ,

V. Yahia ,

C. Goyon ,

F. Consoli ,

G. Boutoux and

C. Baccou*: Affiliation:
LULI, Ecole Polytechnique, CNRS, CEA, UPMC, Palaiseau, France
S. Depierreux: Affiliation:
CEA, DAM, DIF, Arpajon, France
V. Yahia: Affiliation:
LULI, Ecole Polytechnique, CNRS, CEA, UPMC, Palaiseau, France
C. Neuville: Affiliation:
CEA, DAM, DIF, Arpajon, France
C. Goyon: Affiliation:
LULI, Ecole Polytechnique, CNRS, CEA, UPMC, Palaiseau, France CEA, DAM, DIF, Arpajon, France
R. De Angelis: Affiliation:
Associazione Euratom-ENEA sulla Fusione, Frascati, Rome, Italy
F. Consoli: Affiliation:
Associazione Euratom-ENEA sulla Fusione, Frascati, Rome, Italy
J.E. Ducret: Affiliation:
CELIA (Centre Lasers Intenses et Applications), UMR 5107, Université Bordeaux, CNRS, CEA, Talence, France
G. Boutoux: Affiliation:
CELIA (Centre Lasers Intenses et Applications), UMR 5107, Université Bordeaux, CNRS, CEA, Talence, France
J. Rafelski: Affiliation:
Department of Physics, The University of Arizona, Tucson, Arizona
C. Labaune: Affiliation:
LULI, Ecole Polytechnique, CNRS, CEA, UPMC, Palaiseau, France
*: Address correspondence and reprint requests to: C. Baccou, LULI, Ecole Polytechnique, CNRS, CEA, UPMC, 91128 Palaiseau, France E-mail: claire.baccou@polytechnique.edu

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Abstract

The development of high-intensity lasers has opened the field of nuclear reactions initiated by laser-accelerated particles. One possible application is the production of aneutronic fusion reactions for clean fusion energy production. We propose an innovative scheme based on the use of two targets and present the first results obtained with the ELFIE facility (at the LULI Laboratory) for the proton–boron-11 (p–11B) fusion reaction. A proton beam, accelerated by the Target Normal Sheat Acceleration mechanism using a short laser pulse (12 J, 350 fs, 1.056 µm, 1019 W cm−2), is sent onto a boron target to initiate fusion reactions. The number of reactions is measured with particle diagnostics such as CR39 track-detectors, active nuclear diagnostic, Thomson Parabola, magnetic spectrometer, and time-of-flight detectors that collect the fusion products: the α-particles. Our experiment shows promising results for this scheme. In the present paper, we discuss its principle and advantages compared with another scheme that uses a single target and heating mechanisms directly with photons to initiate the same p–11B fusion reaction.

Keywords

Aneutronic reactions Proton–boron fusion reaction Laser-accelerated ions Target normal sheath acceleration Particle diagnostics

Type: Research Article
Information: Laser and Particle Beams , Volume 33 , Issue 1 , March 2015 , pp. 117 - 122

DOI: https://doi.org/10.1017/S0263034615000178 [Opens in a new window]
Copyright: Copyright © Cambridge University Press 2015

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REFERENCES

Ajzenberg-Selove, F. (1990). Energy levels of light nuclei A = 12. Nucl. Phys. A 506, 1–158.CrossRef Google Scholar

Becker, H.W., Rolfs, C. & Trautvetter, H. P. (1987). Low-energy cross sections for 11B(p,3α). Zeitschriftfür Physik A – Atom. Nucl. 327, 341–355.Google Scholar

Belyaev, V. S., Matafonov, A. P., Vinogradov, V. I., Krainov, V. P., Lisitsa, V. S., Roussetski, A. S., Ignatyev, G. N. & Andrianov, V. P. (2005). Observation of neutronless fusion reactions in picosecond laser plasmas. Phys. Rev. E 72, 026406.Google Scholar

Belyaev, V. S., Vinogradov, V. I., Matafonov, A. P., Rybakov, S. M., Krainov, V. P., Lisitsa, V. S., Andrianov, V. P., Ignatiev, G. N., Bushuev, V. S., Gromov, A. I., Rusetsky, A. S.&Dravin, V. A. (2009). Excitation of promising nuclear fusion reactions in picosecond laser plasmas. Phys. Atom. Nucl. 72, 1077–1098.CrossRef Google Scholar

Bonnet, T., Comet, M., Denis-Petit, D., Gobet, F., Hannachi, F., Tarisien, M., Versteegen, M. & Aleonard, M. M. (2013). Response functions of imaging plates to photons, electrons and 4He particles. Rev. Sci. Instrum. 84, 103510.Google Scholar

Fews, A. P., Norreys, P. A., Beg, F. N., Bell, A. R., Dangor, A. E., Danson, C. N., Lee, P. & Rose, S. J. (1994). Plasma ion emission from high intensity picosecond laser pulse interactions with solid target. Phys. Rev. Lett. 73, 1801–1804.CrossRef Google Scholar

Fleischer, R. L., Price, P. B. & Walker, R. M. (1965). Ion explosion spike mechanism for formation of charged particle tracks in solids. J. Appl. Phys. 36, 3645–3652.Google Scholar

Floux, F., Cognard, D., Denoeud, L-G., Piar, G., Parisot, D., Bobin, J. L., Delobeau, F. & Fauquignon, C. (1970). Nuclear fusion reactions in solid-deuterium laser-produced plasma. Phys. Rev. A 1, 821–824.Google Scholar

Fuchs, J., Antici, P., D'Humières, E., Lefebvre, E., Borghesi, M., Brambrink, E., Cecchetti, C. A., Kaluza, M., Malka, V., Manclossi, M., Meyroneinc, S., Mora, P., Schreiber, J., Toncian, T., Pépin, P. & Audebert, P. (2006). Laser-driven proton scaling laws and new paths towards energy increase. Nat. Phys. 2, 48–54.CrossRef Google Scholar

Krainov, V. P. (2005). Laser induced fusion in boron-hydrogen mixture. Laser Phys. Lett. 2, 89–93.Google Scholar

Labaune, C., Baccou, C., Depierreux, S., Goyon, C., Loisel, G., Yahia, V. & Rafelski, J. (2013). Fusion reactions initiated by laser-accelerated particle beams in a laser-produced plasma. Nat. Comm. 4, 2506.Google Scholar

Lalousis, P., Hora, H. & Moustaizis, S. (2014). Optimized boron fusion with magnetic trapping by laser driven plasma block initiation at nonlinear forced driven ultrahigh acceleration. Laser Part. Beams 32, 409–411.Google Scholar

Ledingham, K. W. D., McKenna, P., McCanny, T., Shimizu, S., Yang, J. M., Robson, L., Zweit, J., Gillies, J. M., Bailey, J., Chimon, G. N., Clarke, R. J., Neely, D., Norreys, P. A., Collier, J. L., Singhal, R. P., Wei, M. S., Mangles, S. P. D., Nilson, P., Krushelnick, K. & Zepf, M. (2004). High power laser production of short-lived isotopes for positron emission tomography. J. Phys. D: Appl. Phys. 37, 2341–2345.Google Scholar

Lifschitz, A. F., Farengo, R. & Arista, N. R. (2000). Ionization, stopping, and thermalization of hydrogen and boron beams injected in fusion plasmas. Phys. Plasmas 7, 3036–3041.Google Scholar

Lindl, J. (1995). Development of the indirect drive approach to inertial confinement fusion and the target physics basis for ignition and gain. Phys. Plasmas 2, 3933–4024.Google Scholar

Macchi, A., Borghesi, M. & Passoni, M. (2013). Ion acceleration by superintense laser-plasma interaction. Rev. Mod. Phys. 85, 751–793.Google Scholar

Martinez-Val, J. M., Eliezer, S., Piera, M. & Velarde, G. (1996). Ion acceleration by superintense laser-plasma interaction. Phys. Lett. A 216, 142–152.CrossRef Google Scholar

McCall, G. H., Young, F., Ehler, A. W., Kephart, J. F. & Godwin, R. P. (1973). Neutron emission from laser-produced plasma. Phys. Rev. Lett. 30, 1116–1118Google Scholar

Mora, P. (2003). Plasma expansion into a vacuum. Phys. Rev. Lett. 90, 185002.Google Scholar

Moreau, D. C. (1977). Potentiality of the proton-boron fuel for controlled thermonuclear fusion. Nucl. Fusion 17, 13–20.Google Scholar

Nevins, W. M. & Swain, R. (2000). The thermonuclear fusion rate coefficient for p-¹¹B reaction. Nucl. Fusion 40, 865–872.Google Scholar

Picciotto, A., Margarone, D., Velyhan, A., Belluti, P., Krasa, J., Szydlowsky, A., Bertuccio, G., Shi, Y., Mangione, A., Prokupek, J., Malinowska, A., Krousky, E., Ullschmied, J., Laska, L., Kucharuk, M. & Korn, G. (2014). Boron-Proton Nuclear-Fusion Enhancement Induced in Boron-Doped Silicon Targets by Low-Contrast Pulsed Laser. Phys. Rev. X 4, 031030.Google Scholar

Snavely, R. A., Zhang, B., Akli, K., Chen, Z., Freeman, R. R., Gu, P., Hatchett, S. P., Hey, D., Hill, J., Key, M. H., Izawa, Y., King, J., Kitagawa, Y., Kodama, R., Langdon, A. B., Lasinski, B. F., Lei, A., MacKinnon, A. J., Patel, P., Stephens, R., Tampo, M., Tanaka, K. A., Town, R., Toyama, Y., Tsutsumi, T., Wilks, S. C., Yabuuchi, T. & Zheng, J. (2007). Laser generated proton beam focusing and high temperature isochoric heating of solid matter. Phys. Plasmas 14, 092703.Google Scholar

Spencer, I., Ledingham, K. W. D., Singhal, R. P., McCanny, T., McKenna, P., Clark, E. L., Krushelnick, K., Zepf, M., Beg, F. N., Tatarakis, M., Dangor, A.E., Norreys, P.A., Clarke, R. J., Allott, R. M. & Ross, I. N. (2001). Laser generation of proton beams for the production of short-lived positron emitting radioisotopes. Nucl. Instrum. Meth. Phys. Res. B 183, 449–458.Google Scholar

Strickland, D. & Mourou, G. (1985). Compression of amplified chirped optical pulses. Opt. Commun. 55, 447–449.Google Scholar

Tabak, M., Munro, D. H. & Lindl, J. D. (1990). Ignition and high gain with ultrapowerful lasers. Phys. Fluids B 2, 1007–1014.Google Scholar

von Seggern, H. (1992). X-ray imaging with photostimulable phosphors. Nucl. Instrum. Meth. Phys. Res. A 322, 467–471.Google Scholar

Yamanaka, C., Yamanaka, T., Sasaki, T., Yoshida, K. & Waki, M. (1972). Anomalous heating of a plasma by a laser. Phys. Rev. A 6, 2335–2342.Google Scholar

Wilks, S. C., Langdon, A. B., Cowan, T. E., Roth, M., Singh, M., Hatchett, S., Key, M. H., Pennington, D., MacKinnon, A. & Snavely, R. A. (2001). Energetic proton generation in ultra-intense laser-solid interactions. Phys. Plasmas 8, 542–549.Google Scholar

Zepf, M., Clark, E. L., Beg, F. N., Clarke, R. J., Dangor, A. E., Gopal, A., Krushelnick, K., Norreys, P. A., Tatarakis, M., Wagner, U. & Wei, M. S. (2003). Proton acceleration from high-intensity laser interactions with thin foil targets. Phys. Rev. Lett. 90, 064801CrossRef Google Scholar PubMed

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Consoli, F. Angelis, R. De Bonasera, A. Sura, J. Andreoli, P. Cristofari, G. Cipriani, M. Giorgio, G. Di Ingenito, F. Barbarino, M. Labaune, C. Baccou, C. Depierreux, S. Goyon, C. and Yahia, V. 2016. Study on a compact and adaptable Thomson Spectrometer for laser-initiated11B(p,α)8Be reactions and low-medium energy particle detection. Journal of Instrumentation, Vol. 11, Issue. 05, p. C05010.

Giulietti, D. Andreoli, P. Batani, D. Bonasera, A. Boutoux, G. Burgy, F. Cipriani, M. Consoli, F. Cristofari, G. De Angelis, R. Di Giorgio, G. Ducret, J.E. Ingenito, F. Jakubowska, K. Verona, C. and Verona-Rinati, G. 2017. Laser-plasma energetic particle production for aneutronic nuclear fusion experiments. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, Vol. 402, Issue. , p. 373.

Korn, Georg Silva, Luis O. Moustaizis, S. D. Lalousis, P. Hora, H. and Korn, G. 2017. Numerical studies on alpha production from high energy proton beam interaction with Boron. Vol. 10241, Issue. , p. 102411L.

Ingenito, Francesco Andreoli, Pierluigi Batani, Dimitri Bonasera, Aldo Boutoux, Guillaume Burgy, Frederic Cipriani, Mattia Consoli, Fabrizio Cristofari, Giuseppe De Angelis, Riccardo Di Giorgio, Giorgio Ducret, Jean Eric Giulietti, Danilo Jakubowska, Katarzyna Torrisi, L. and Cutroneo, M. 2018. Directional Track Selection Technique in CR39 SSNTD for lowyield reaction experiments. EPJ Web of Conferences, Vol. 167, Issue. , p. 05006.

Gus’kov, Sergey Korneev, Philipp Torrisi, L. and Cutroneo, M. 2018. Aneutronic pB-Reaction in Magnetized Inertial Confined Plasma of Laser-Accelerated Particles. EPJ Web of Conferences, Vol. 167, Issue. , p. 05001.

De Angelis, Riccardo Giulietti, Danilo Calcagnile, Lucio Quarta, Gianluca Andreoli, Pierluigi Cipriani, Mattia Consoli, Fabrizio Cristofari, G. Delle Side, Domenico Di Giorgio, Giorgio Ingenito, Francesco Maruccio, Lucio Torrisi, L. and Cutroneo, M. 2018. α particle space distribution from fusion reactions in Boron irradiated by mono-energetic protons. EPJ Web of Conferences, Vol. 167, Issue. , p. 05005.

Tayyab, M Bagchi, S Moorti, A and Chakera, J A 2019. Experimental investigation on nuclear reactions using a laser-accelerated proton and deuteron beam. Plasma Physics and Controlled Fusion, Vol. 61, Issue. 11, p. 115007.

Cipriani, M. Consoli, F. Andreoli, P.L. Batani, D. Bonasera, A. Boutoux, G. Burgy, F. Cristofari, G. Angelis, R. De Giorgio, G. Di Ducret, J.E. Flamigni, A. Giulietti, D. Jakubowska, K. Verona, C. and Verona-Rinati., G. 2019. Spectral characterization by CVD diamond detectors of energetic protons from high-repetition rate laser for aneutronic nuclear fusion experiments. Journal of Instrumentation, Vol. 14, Issue. 01, p. C01027.

Belyaev, V. S. Matafonov, A. P. Krainov, V. P. Kedrov, A. Yu. Zagreev, B. V. Rusetsky, A. S. Borisenko, N. G. Gromov, A. I. Lobanov, A. V. and Lisitsa, V. S. 2020. Simultaneous Investigation of the Nuclear Reactions $${}^{11}$$B$$\boldsymbol{(p,3\alpha)}$$ and $${}^{11}$$B$$\boldsymbol{(p,n)^{11}}$$C as a New Tool for Determining the Absolute Yield of Alpha Particles in Picosecond Plasmas. Physics of Atomic Nuclei, Vol. 83, Issue. 5, p. 641.

Consoli, Fabrizio De Angelis, Riccardo Andreoli, Pierluigi Bonasera, Aldo Cipriani, Mattia Cristofari, Giuseppe Di Giorgio, Giorgio Giulietti, Danilo and Salvadori, Martina 2020. Diagnostic Methodologies of Laser-Initiated 11B(p,α)2α Fusion Reactions. Frontiers in Physics, Vol. 8, Issue. ,

Belloni, Fabio and Batani, Katarzyna 2022. Multiplication Processes in High-Density H-11B Fusion Fuel. Laser and Particle Beams, Vol. 2022, Issue. ,

Schollmeier, Marius S. Shirvanyan, Vahe Capper, Christie Steinke, Sven Higginson, Adam Hollinger, Reed Morrison, John T. Nedbailo, Ryan Song, Huanyu Wang, Shoujun Rocca, Jorge J. Korn, Georg and Batani, Dimitri 2022. Investigation of Proton Beam-Driven Fusion Reactions Generated by an Ultra-Short Petawatt-Scale Laser Pulse. Laser and Particle Beams, Vol. 2022, Issue. ,

Qin, T.-T. Luo, W. Lan, H.-Y. and Wang, W.-M. 2022. Ultrafast probing of plasma ion temperature in proton–boron fusion by nuclear resonance fluorescence emission spectroscopy. Matter and Radiation at Extremes, Vol. 7, Issue. 3,

Kong, Defeng Xu, Shirui Shou, Yinren Gao, Ying Mei, Zhusong Pan, Zhuo Liu, Zhipeng Cao, Zhengxuan Liang, Yulan Peng, Ziyang Wang, Pengjie Luo, Di Li, Yang Li, Zhi Xie, Huasheng Zhang, Guoqiang Luo, Wen Zhao, Jiarui Chen, Shiyou Geng, Yixing Zhao, Yanying Xue, Jianming Yan, Xueqing Ma, Wenjun and Belloni, Fabio 2022. Alpha-Particle Generation from H-11B Fusion Initiated by Laser-Accelerated Boron Ions. Laser and Particle Beams, Vol. 2022, Issue. ,

Ning, Xiaochuan Liang, Tianyi Wu, Dong Liu, Shujun Liu, Yangchun Hu, Tianxing Sheng, Zhengmao Ren, Jieru Jiang, Bowen Zhao, Yongtao Hoffmann, Dieter H. H. He, X.T. and Batani, Dimitri 2022. Laser-Driven Proton-Boron Fusions: Influences of the Boron State. Laser and Particle Beams, Vol. 2022, Issue. ,

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Belyaev, V. S. Matafonov, A. P. Andreev, S. N. Tarakanov, V. P. Krainov, V. P. Lisitsa, V. S. Kedrov, A. Yu. Zagreev, B. V. Rusetskii, A. S. Borisenko, N. G. Gromov, A. I. and Lobanov, A. V. 2022. Investigation of the Yield of the Nuclear Reaction $${}^{{11}}$$B($${p,3\alpha}$$ ) Initiated by Powerful Picosecond Laser Radiation. Physics of Atomic Nuclei, Vol. 85, Issue. 1, p. 31.

Andreev, S. N. Belyaev, V. S. Matafonov, A. P. Tarakanov, V. P. Zagreev, B. V. Krainov, V. P. Mukhanov, S. A. and Lobanov, A. V. 2022. Numerical Simulation of the Yield of α Particles and Neutrons from the 11B(p, 3α) and 11B(p, n)11C Nuclear Reactions Induced by Intense Picosecond Laser Radiation. Journal of Experimental and Theoretical Physics, Vol. 135, Issue. 1, p. 26.

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New scheme to produce aneutronic fusion reactions by laser-accelerated ions

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