Relativistic Particle Acceleration due to Magnetically Driven Reconnection at low-β using Laser-Powered Capacitive Coils

POSTER

Abstract

Magnetic Reconnection is the ubiquitous astrophysical process in which a plasma rapidly converts magnetic field energy into a combination of flow energy, thermal energy and non-thermal energetic particles. In extreme astrophysical environments like black holes and neutron stars, acceleration mechanisms (including Fermi acceleration, betatron acceleration, reconnection electric field acceleration and electric field acceleration across magnetic fields) can accelerate particles in magnetic reconnection to a relativistic regime. Only recently, [1] has this environment been experimentally studied using short-pulse lasers to drive parallel currents in a capacitively coupled quasi-axisymmetric laser coil system. This process achieves ~150 Tesla and σe = 10 relativistic reconnection. We further demonstrate an empirically derived relativistic scaling law for this astrophysical reconnection regime. Corroborating with 3D and 2D VPIC simulation, preliminary experimental results are validated against these analytic models.

[1]: A. Chien, L. Gao, S. Zhang, H. Ji, E. G. Blackman, W. Daughton, A. Stanier, A. Le, F. Guo, R. Follett, H. Chen, G. Fiksel, G. Bleotu, R. C. Cauble, S. N. Chen, A. Fazzini, K. Flippo, O. French, D. H. Froula, J. Fuchs, S. Fujioka, K. Hill, S. Klein, C. Kuranz, P. Nilson, A. Rasmus, and R. Takizawa, “Non-thermal electron acceleration from magnetically driven reconnection in a laboratory plasma,” Nature Physics 19, 254–262 (2023)

*This work was supported Princeton University and PPPL with support from FES, USDOE, and LLE's OMEGA facility. Additional computational and experimental support was received from LANL and Osaka University.

Publication: [1] A. Chien, L. Gao, S. Zhang, H. Ji, E. G. Blackman, W. Daughton, A. Stanier, A. Le, F. Guo, R. Follett, H. Chen, G. Fiksel, G. Bleotu, R. C. Cauble, S. N. Chen, A. Fazzini, K. Flippo, O. French, D. H. Froula, J. Fuchs, S. Fujioka, K. Hill, S. Klein, C. Kuranz, P. Nilson, A. Rasmus, and R. Takizawa, "Non-thermal electron acceleration from magnetically driven reconnection in a laboratory plasma," Nature Physics 19, 254–262 (2023)
[2] A. Chien, L. Gao, H. Ji, X. Yuan, E. G. Blackman, H. Chen, P. C. Efthimion, G. Fiksel, D. H. Froula, K. W. Hill, K. Huang, Q. Lu, J. D. Moody, and P. M. Nilson, "Study of a magnetically driven reconnection platform using ultrafast proton radiography," Phys. Plasmas 26, 062113 (2019)
[3] H. Ji, L. Gao,, A. Chien,, S. Zhang,, E. Blackman, G. Pomraning, K. Sakai, F. Guo, X. Li, and A. Stanier "Study of magnetic reconnection at low-$\beta$ using laser-powered capacitor coils" [Submitted] (2023)
[4] S. Zhang, A. Chien, L. Gao, H. Ji, E. Blackman, R. Follett, D. Froula, J. Katz, C. Li, A. Birkel, R. Petrasso, J. Moody, and H. Chen, "Ion and Electron Acoustic Bursts during Anti-Parallel Reconnection Driving by Lasers," Nature Physics 19, 909 (2023)

Presenters

  • Geoffrey Pomraning

    • Princeton University

Authors

  • Geoffrey Pomraning

    • Princeton University

  • Kian Orr

    • Princeton University

  • Yang Zhang

    • Princeton
    • Princeton University & UCAR

  • Brandon K Russell

    • Princeton University
    • University of Michigan

  • Lan Gao

    • Princeton Plasma Physics Laboratory (PPPL)

  • Hantao Ji

    • Princeton Plasma Physics Laboratory
    • Princeton University

  • Xiaocan Li

    • Los Alamos National Laboratory
    • Los Alamos National Laboratory (LANL)

  • Adam J Stanier

    • Los Alamos National Laboratory (LANL)
    • Los Alamos National Laboratory

  • Fan Guo

    • Los Alamos National Laboratory (LANL)