Refining pulsar radio emission due to streaming instabilities: Linear theory and PIC simulations in a wide parameter range

TL;DR

This study combines linear kinetic theory and PIC simulations to explore the conditions under which streaming instabilities can produce coherent pulsar radio emission, identifying key parameter ranges that facilitate this process.

Contribution

It extends previous analyses by considering a wider parameter space and validating analytical predictions with numerical simulations for pulsar plasma conditions.

Findings

Growth rates depend on beam-to-background density ratio and streaming velocity.

Maximum growth occurs at intermediate beam velocities.

Wave phase coherence is confirmed through fractional bandwidth calculations.

Abstract

Several important mechanisms that explain the coherent pulsar radio emission rely on streaming (or beam) instabilities of the relativistic pair plasma in a pulsar magnetosphere. However, it is still not clear whether a streaming instability by itself is sufficient to explain the observed coherent radio emission. Due to the relativistic conditions that are present in the pulsar magnetosphere, kinetic instabilities could be quenched. Moreover, uncertainties regarding specific model-dependent parameters impede conclusions concerning this question. We aim to constrain the possible parameter range for which a streaming instability could lead to pulsar radio emission, focusing on the transition between strong and weak beam models, beam drift speed, and temperature dependence of the beam and background plasma components. We solve a linear relativistic kinetic dispersion relation appropriate for pulsar conditions in a more general way than in previous studies, considering a wider parameter range. The analytical results are validated by comparison with relativistic kinetic particle-in-cell (PIC) numerical simulations. We obtain growth rates as a function of background and beam densities, temperatures, and streaming velocities while finding a remarkable agreement of the linear dispersion predictions and numerical simulation results in a wide parameter range. Monotonous growth is found when increasing the beam-to-background density ratio. With growing beam velocity, the growth rates firstly increase, reach a maximum and decrease again for higher beam velocities. A monotonous dependence on the plasma temperatures is found, manifesting in an asymptotic behaviour when reaching colder temperatures. We show that the generated waves are phase-coherent by calculating the fractional bandwidth. We provide an explicit parameter range of plasma conditions for efficient pulsar radio emission.