Polarized quasiperiodic structures in pulsar radio emission reflect temporal modulations of non-stationary plasma flow

TL;DR

This study analyzes high-resolution polarimetric pulsar data to investigate microstructure periodicities, revealing that microstructure timescales are consistent across polarization states and correlated with pulsar period, informing models of plasma flow modulation.

Contribution

The paper introduces a new method for analyzing low-amplitude microstructure fluctuations and demonstrates that microstructure timescales are polarization-independent and linked to pulsar period.

Findings

Microstructure timescale $P_{}$ is consistent across all polarization parameters.

No evidence of vacuum curvature radiation in microstructure.

Strong correlation between $P_{}$ and pulsar period $P$.

Abstract

Bright single pulses of many radio pulsars show rapid intensity fluctuations (called microstructure) when observed with time resolutions of tens of microseconds. Here, we report an analysis of Arecibo 59.5 $\mu$sec-resolution polarimetric observations of 11 P-band and 32 L-band pulsars with periods ranging from 150 msec to 3.7 sec. These higher frequency observations forms the most reliable basis for detailed microstructure studies. Close inspection of individual pulses reveals that most pulses exhibit quasiperiodicities with a well-defined periodicity timescale ($P_{\mu}$). While we find some pulses with deeply modulating microstructure, most pulses show low-amplitude modulations on top of broad smooth subpulses features, thereby making it difficult to infer periodicities. We have developed a method for such low-amplitude fluctuations wherein a smooth subpulse envelope is subtracted from each de-noised subpulse; the fluctuating portion of each subpulse is then used to estimate $P_{\mu}$ via autocorrelation analysis. We find that the microstructure timescale $P_{\mu}$ is common across all Stokes parameters of polarized pulsar signals. Moreover, no clear signature of curvature radiation in vacuum in highly resolved microstructures was found. Our analysis further shows strong correlation between $P_\mu$ and the pulsar period $P$. We discuss implications of this result in terms of a coherent radiation model wherein radio emission arises due to formation and acceleration of electron-positron pairs in an inner vacuum gap over magnetic polar cap, and a subpulse corresponds to a series of non-stationary sparking discharges. We argue that in this model, $P_{\mu}$ reflects the temporal modulation of non-stationary plasma flow.