A direct measurement of a relativistic pair-plasma beam instability at The HiRadMat Facility (CERN)

Jack WD Halliday; Charles D Arrowsmith; Alice Marie Goillot; Pascal Simon; Vasiliki Stergiou; Fiona Zhang; Pablo Jaime Bilbao; Emily M Andersen; Archie F.A. Bott; Stephane Burger; Hui Chen; Filipe D Cruz; Tristan Davenne; Ilias Efthymiopoulos; Dustin H Froula; Jon Tomas Gudmundsson; Daniel J Haberberger; Tom Hodge; Todd Huffman; Sam Iaquinta; Eva E Los; Francesco Miniati; Brian Reville; Panayiota Rousiadou; Subir Sarkar; Alexander A Schekochihin; Luis O Silva; Raspberry Simpson; Raoul M Trines; Thibault Vieu; Nikolaos Charitonidis; Robert Bingham; Gianluca Gregori

A direct measurement of a relativistic pair-plasma beam instability at The HiRadMat Facility (CERN)

ORAL

Abstract

Relativistic electron-positron plasmas are believed to occur in extreme astrophysical environments such as the jets from black-holes and neutron-star magnetospheres. Their behaviour is quite different from typical electron-ion plasmas due to matter-antimatter symmetry and they are believed to be fundamental in determining the dynamics of such astrophysical systems.

In experiments performed in 2023, we demonstrated the first experimental realisation of relativistic electron-positron pair plasmas [1], driven by the 440 GeV/c proton beam at CERN’s HiRadMat Facility [2]. The pair-plasma beam was directed through an inductive plasma discharge to explore kinetic instabilities mediating its interaction with an ambient plasma.

In our previous work, limited diagnostic sensitivity meant we were unable to directly measure signatures of kinetic instabilities. This presentation includes new results from a follow-up experiment in which we fielded a refined in-crystal Faraday rotation instrument. This enabled the direct diagnosis of magnetic field amplification by the filamentation instability. To our knowledge this is the first direct measurement of a pair beam instability in the laboratory.

[1] Arrowsmith, et al. Laboratory realization of relativistic pair-plasma beams. Nat Commun 15, 5029 (2024).

[2] I. Efthymiopoulos et al. (2011) “HiRadMat: A new Irradiation Facility for Material Testing at CERN” Proc. 2nd Int. Particle Accelerator Conf. (IPAC’11).

^*This project has received funding from the European Union’s Horizon Europe Research and Innovation programme under Grant Agreement No 101057511 (EURO-LABS).

Oct. 9, 2024, 4:00 PM – Oct. 9, 2024, 4:12 PM

Presenters

Jack WD Halliday
- Rutherford Appleton Laboratory / STFC
- University of Oxford

Authors

Jack WD Halliday
- Rutherford Appleton Laboratory / STFC
- University of Oxford
Charles D Arrowsmith
- University of Oxford
Alice Marie Goillot
- CERN
Pascal Simon
- GSI
Vasiliki Stergiou
- CERN
Fiona Zhang
- University of Oxford
Pablo Jaime Bilbao
- Instituto Superior Tecnico
- GoLP/IPFN, IST, ULisboa, Portugal
Emily M Andersen
- CERN
Archie F.A. Bott
- University of Oxford
Stephane Burger
- CERN
Hui Chen
- LLNL
- Lawrence Livermore National Laboratory
Filipe D Cruz
- Instituto Superior Tecnico
Tristan Davenne
- Rutherford Appleton Laboratory
Ilias Efthymiopoulos
- CERN
Dustin H Froula
- University of Rochester
- University of Rochester - Laboratory for Laser Energetics
Jon Tomas Gudmundsson
- University of Iceland
Daniel J Haberberger
- Lab for Laser Energetics
Tom Hodge
- AWE
Todd Huffman
- University of Oxford
Sam Iaquinta
- University of Oxford
Eva E Los
- Imperial College London
Francesco Miniati
- University of Oxford
Brian Reville
- Max-Planck-Institut für Kernphysik
Panayiota Rousiadou
- University of Ioannina
Subir Sarkar
- University of Oxford
Alexander A Schekochihin
- University of Oxford
Luis O Silva
- Instituto Superior Tecnico
- GoLP/IPFN, IST, ULisboa, Portugal
Raspberry Simpson
- Lawrence Livermore National Laboratory
Raoul M Trines
- STFC Rutherford Appleton Laboratory
Thibault Vieu
- Max-Planck-Institut für Kernphysik
Nikolaos Charitonidis
- CERN
Robert Bingham
- University of Strathclyde
Gianluca Gregori
- University of Oxford