Simulations of Astrophysically Relevant Pair Beam Instabilities in a Laboratory Context (2501.14518v1)

Abstract: The interaction of TeV blazars emitted gamma-rays with the extragalactic background photons gives rise to a relativistic beam of electron-positron ($e^- e^+$) pairs propagating through the intergalactic medium, producing a cascade through up-scattering low-energy photons. Plasma instability is considered one of the underlying energy-loss processes of the beams. We employ particle-in-cell (PIC) simulations to study the plasma instabilities of ultra-relativistic pair beams propagating in a denser background plasma, using the parameters designed to replicate astrophysical jets under laboratory conditions. In an astrophysical scenario with a broad, dilute beam, electromagnetic instability can be disregarded because its growth rate is slower than that of electrostatic instability, indicating the electromagnetic modes are suppressed. We calculate the physical limit of density contrast at which a warm beam achieves suppression of electromagnetic instabilities in laboratory experiments, consistent with the physically relevant conditions for Blazar-induced beams. We have used a composite Cauchy distribution for the beam particles, which is more realistic in representing the non-Maxwellian nature of pair beams, improving upon previous studies. We investigate the interplay between the magnetic field forming from localized currents and transverse beam momentum spread. We extrapolate to the non-linear feedback of instability where the beam is energetically broadened. We observe that the instability generates a negligible angular broadening for Blazar-Induced beams.