Electron acceleration by wave turbulence in a magnetized plasma

A. Rigby; F. Cruz; B. Albertazzi; R. Bamford; A. R. Bell; J. E. Cross; F. Fraschetti; P. Graham; Y. Hara; P. M. Kozlowski; Y. Kuramitsu; D. Q. Lamb; S. Lebedev; J. R. Marques; F. Miniati; T. Morita; M. Oliver; B. Reville; Y. Sakawa; S. Sarkar; C. Spindloe; R. Trines; P. Tzeferacos; L. O. Silva; R. Bingham; M. Koenig; G. Gregori

doi:10.1038/s41567-018-0059-2

Electron acceleration by wave turbulence in a magnetized plasma

A. Rigby, F. Cruz, B. Albertazzi, R. Bamford, A. R. Bell, J. E. Cross, F. Fraschetti, P. Graham, Y. Hara, P. M. Kozlowski, Y. Kuramitsu, D. Q. Lamb, S. Lebedev, J. R. Marques, F. Miniati, T. Morita, M. Oliver, B. Reville, Y. Sakawa, S. SarkarC. Spindloe, R. Trines, P. Tzeferacos, L. O. Silva, R. Bingham, M. Koenig, G. Gregori

Research output: Contribution to journal › Article › peer-review

20 Citations (Scopus)

Abstract

Astrophysical shocks are commonly revealed by the non-thermal emission of energetic electrons accelerated in situ ^1-3 . Strong shocks are expected to accelerate particles to very high energies ^4-6 ; however, they require a source of particles with velocities fast enough to permit multiple shock crossings. While the resulting diffusive shock acceleration ⁴ process can account for observations, the kinetic physics regulating the continuous injection of non-thermal particles is not well understood. Indeed, this injection problem is particularly acute for electrons, which rely on high-frequency plasma fluctuations to raise them above the thermal pool ^7,8 . Here we show, using laboratory laser-produced shock experiments, that, in the presence of a strong magnetic field, significant electron pre-heating is achieved. We demonstrate that the key mechanism in producing these energetic electrons is through the generation of lower-hybrid turbulence via shock-reflected ions. Our experimental results are analogous to many astrophysical systems, including the interaction of a comet with the solar wind ⁹ , a setting where electron acceleration via lower-hybrid waves is possible.

Original language	English
Pages (from-to)	475-479
Number of pages	5
Journal	Nature Physics
Volume	14
Issue number	5
DOIs	https://doi.org/10.1038/s41567-018-0059-2
Publication status	Published - May 1 2018
Externally published	Yes

All Science Journal Classification (ASJC) codes

Physics and Astronomy(all)

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10.1038/s41567-018-0059-2

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Rigby, A., Cruz, F., Albertazzi, B., Bamford, R., Bell, A. R., Cross, J. E., Fraschetti, F., Graham, P., Hara, Y., Kozlowski, P. M., Kuramitsu, Y., Lamb, D. Q., Lebedev, S., Marques, J. R., Miniati, F., Morita, T., Oliver, M., Reville, B., Sakawa, Y., ... Gregori, G. (2018). Electron acceleration by wave turbulence in a magnetized plasma. Nature Physics, 14(5), 475-479. https://doi.org/10.1038/s41567-018-0059-2

Rigby, A, Cruz, F, Albertazzi, B, Bamford, R, Bell, AR, Cross, JE, Fraschetti, F, Graham, P, Hara, Y, Kozlowski, PM, Kuramitsu, Y, Lamb, DQ, Lebedev, S, Marques, JR, Miniati, F, Morita, T, Oliver, M, Reville, B, Sakawa, Y, Sarkar, S, Spindloe, C, Trines, R, Tzeferacos, P, Silva, LO, Bingham, R, Koenig, M & Gregori, G 2018, 'Electron acceleration by wave turbulence in a magnetized plasma', Nature Physics, vol. 14, no. 5, pp. 475-479. https://doi.org/10.1038/s41567-018-0059-2

@article{a93ad2f9b9854ce682dc584e7098b3cd,

title = "Electron acceleration by wave turbulence in a magnetized plasma",

abstract = " Astrophysical shocks are commonly revealed by the non-thermal emission of energetic electrons accelerated in situ 1-3 . Strong shocks are expected to accelerate particles to very high energies 4-6 ; however, they require a source of particles with velocities fast enough to permit multiple shock crossings. While the resulting diffusive shock acceleration 4 process can account for observations, the kinetic physics regulating the continuous injection of non-thermal particles is not well understood. Indeed, this injection problem is particularly acute for electrons, which rely on high-frequency plasma fluctuations to raise them above the thermal pool 7,8 . Here we show, using laboratory laser-produced shock experiments, that, in the presence of a strong magnetic field, significant electron pre-heating is achieved. We demonstrate that the key mechanism in producing these energetic electrons is through the generation of lower-hybrid turbulence via shock-reflected ions. Our experimental results are analogous to many astrophysical systems, including the interaction of a comet with the solar wind 9 , a setting where electron acceleration via lower-hybrid waves is possible.",

author = "A. Rigby and F. Cruz and B. Albertazzi and R. Bamford and Bell, {A. R.} and Cross, {J. E.} and F. Fraschetti and P. Graham and Y. Hara and Kozlowski, {P. M.} and Y. Kuramitsu and Lamb, {D. Q.} and S. Lebedev and Marques, {J. R.} and F. Miniati and T. Morita and M. Oliver and B. Reville and Y. Sakawa and S. Sarkar and C. Spindloe and R. Trines and P. Tzeferacos and Silva, {L. O.} and R. Bingham and M. Koenig and G. Gregori",

note = "Funding Information: PD/BD/114307/2016) the Calouste Gulbenkian Foundation and PRACE for awarding access to resource MareNostrum, based in Spain at the Barcelona Supercomputing Center. The PIC simulations were performed at the IST cluster (Lisbon, Portugal), and MareNostrum (Spain). This work was supported in part at the University of Chicago by the US DOE NNSA ASC through the Argonne Institute for Computing in Science under FWP 57789 and the US DOE Office of Science through grant no. DESC0016566. The software used in this work was developed in part by the DOE NNSA ASC-and DOE Office of Science ASCR-supported Flash Center for Computational Science at the University of Chicago. Funding Information: We thank all the LULI technical staff at Ecole Polytechnique for their support during the experiment. The research leading to these results has received funding from the European Research Council under the European Community's Seventh Framework Programme (FP7/2007-2013)/ERC grant agreements no. 256973 and 247039, AWE plc, the Engineering and Physical Sciences Research Council (grant numbers EP/M022331/1, EP/N014472/1, EP/N013379/1 and EP/N002644/1) and the Science and Technology Facilities Council of the United Kingdom. F.C. and L.O.S. acknowledge support from the European Research Council (InPairs ERC-2015-AdG 695088), FCT Portugal (grant no. PD/BD/114307/2016) the Calouste Gulbenkian Foundation and PRACE for awarding access to resource MareNostrum, based in Spain at the Barcelona Supercomputing Center. The PIC simulations were performed at the IST cluster (Lisbon, Portugal), and MareNostrum (Spain). This work was supported in part at the University of Chicago by the US DOE NNSA ASC through the Argonne Institute for Computing in Science under FWP 57789 and the US DOE Office of Science through grant no. DE- SC0016566. The software used in this work was developed in part by the DOE NNSA ASC- and DOE Office of Science ASCR-supported Flash Center for Computational Science at the University of Chicago Funding Information: We thank all the LULI technical staff at {\'E}cole Polytechnique for their support during the experiment. The research leading to these results has received funding from the European Research Council under the European Community{\textquoteright}s Seventh Framework Programme (FP7/2007-2013)/ERC grant agreements no. 256973 and 247039, AWE plc, the Engineering and Physical Sciences Research Council (grant numbers EP/M022331/1, EP/N014472/1, EP/N013379/1 and EP/N002644/1) and the Science and Technology Facilities Council of the United Kingdom. F.C. and L.O.S. acknowledge support from the European Research Council (InPairs ERC-2015-AdG 695088), FCT Portugal (grant no. Publisher Copyright: {\textcopyright} 2018 The Author(s).",

year = "2018",

month = may,

day = "1",

doi = "10.1038/s41567-018-0059-2",

language = "English",

volume = "14",

pages = "475--479",

journal = "Nature Physics",

issn = "1745-2473",

publisher = "Nature Publishing Group",

number = "5",

}

TY - JOUR

T1 - Electron acceleration by wave turbulence in a magnetized plasma

AU - Rigby, A.

AU - Cruz, F.

AU - Albertazzi, B.

AU - Bamford, R.

AU - Bell, A. R.

AU - Cross, J. E.

AU - Fraschetti, F.

AU - Graham, P.

AU - Hara, Y.

AU - Kozlowski, P. M.

AU - Kuramitsu, Y.

AU - Lamb, D. Q.

AU - Lebedev, S.

AU - Marques, J. R.

AU - Miniati, F.

AU - Morita, T.

AU - Oliver, M.

AU - Reville, B.

AU - Sakawa, Y.

AU - Sarkar, S.

AU - Spindloe, C.

AU - Trines, R.

AU - Tzeferacos, P.

AU - Silva, L. O.

AU - Bingham, R.

AU - Koenig, M.

AU - Gregori, G.

N1 - Funding Information: PD/BD/114307/2016) the Calouste Gulbenkian Foundation and PRACE for awarding access to resource MareNostrum, based in Spain at the Barcelona Supercomputing Center. The PIC simulations were performed at the IST cluster (Lisbon, Portugal), and MareNostrum (Spain). This work was supported in part at the University of Chicago by the US DOE NNSA ASC through the Argonne Institute for Computing in Science under FWP 57789 and the US DOE Office of Science through grant no. DESC0016566. The software used in this work was developed in part by the DOE NNSA ASC-and DOE Office of Science ASCR-supported Flash Center for Computational Science at the University of Chicago. Funding Information: We thank all the LULI technical staff at Ecole Polytechnique for their support during the experiment. The research leading to these results has received funding from the European Research Council under the European Community's Seventh Framework Programme (FP7/2007-2013)/ERC grant agreements no. 256973 and 247039, AWE plc, the Engineering and Physical Sciences Research Council (grant numbers EP/M022331/1, EP/N014472/1, EP/N013379/1 and EP/N002644/1) and the Science and Technology Facilities Council of the United Kingdom. F.C. and L.O.S. acknowledge support from the European Research Council (InPairs ERC-2015-AdG 695088), FCT Portugal (grant no. PD/BD/114307/2016) the Calouste Gulbenkian Foundation and PRACE for awarding access to resource MareNostrum, based in Spain at the Barcelona Supercomputing Center. The PIC simulations were performed at the IST cluster (Lisbon, Portugal), and MareNostrum (Spain). This work was supported in part at the University of Chicago by the US DOE NNSA ASC through the Argonne Institute for Computing in Science under FWP 57789 and the US DOE Office of Science through grant no. DE- SC0016566. The software used in this work was developed in part by the DOE NNSA ASC- and DOE Office of Science ASCR-supported Flash Center for Computational Science at the University of Chicago Funding Information: We thank all the LULI technical staff at École Polytechnique for their support during the experiment. The research leading to these results has received funding from the European Research Council under the European Community’s Seventh Framework Programme (FP7/2007-2013)/ERC grant agreements no. 256973 and 247039, AWE plc, the Engineering and Physical Sciences Research Council (grant numbers EP/M022331/1, EP/N014472/1, EP/N013379/1 and EP/N002644/1) and the Science and Technology Facilities Council of the United Kingdom. F.C. and L.O.S. acknowledge support from the European Research Council (InPairs ERC-2015-AdG 695088), FCT Portugal (grant no. Publisher Copyright: © 2018 The Author(s).

PY - 2018/5/1

Y1 - 2018/5/1

N2 - Astrophysical shocks are commonly revealed by the non-thermal emission of energetic electrons accelerated in situ 1-3 . Strong shocks are expected to accelerate particles to very high energies 4-6 ; however, they require a source of particles with velocities fast enough to permit multiple shock crossings. While the resulting diffusive shock acceleration 4 process can account for observations, the kinetic physics regulating the continuous injection of non-thermal particles is not well understood. Indeed, this injection problem is particularly acute for electrons, which rely on high-frequency plasma fluctuations to raise them above the thermal pool 7,8 . Here we show, using laboratory laser-produced shock experiments, that, in the presence of a strong magnetic field, significant electron pre-heating is achieved. We demonstrate that the key mechanism in producing these energetic electrons is through the generation of lower-hybrid turbulence via shock-reflected ions. Our experimental results are analogous to many astrophysical systems, including the interaction of a comet with the solar wind 9 , a setting where electron acceleration via lower-hybrid waves is possible.

AB - Astrophysical shocks are commonly revealed by the non-thermal emission of energetic electrons accelerated in situ 1-3 . Strong shocks are expected to accelerate particles to very high energies 4-6 ; however, they require a source of particles with velocities fast enough to permit multiple shock crossings. While the resulting diffusive shock acceleration 4 process can account for observations, the kinetic physics regulating the continuous injection of non-thermal particles is not well understood. Indeed, this injection problem is particularly acute for electrons, which rely on high-frequency plasma fluctuations to raise them above the thermal pool 7,8 . Here we show, using laboratory laser-produced shock experiments, that, in the presence of a strong magnetic field, significant electron pre-heating is achieved. We demonstrate that the key mechanism in producing these energetic electrons is through the generation of lower-hybrid turbulence via shock-reflected ions. Our experimental results are analogous to many astrophysical systems, including the interaction of a comet with the solar wind 9 , a setting where electron acceleration via lower-hybrid waves is possible.

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U2 - 10.1038/s41567-018-0059-2

DO - 10.1038/s41567-018-0059-2

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SP - 475

EP - 479

JO - Nature Physics

JF - Nature Physics

IS - 5

ER -

Electron acceleration by wave turbulence in a magnetized plasma

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