Giant pulses from the Crab pulsar: A wide-band study

TL;DR

This study uses wide-band, high-resolution radio observations with the WSRT to analyze the faint end of the Crab pulsar's giant pulse emission, revealing new insights into their properties and occurrence at different pulse phases.

Contribution

It is the first to detect giant pulses simultaneously at main- and interpulse phases within a single rotation, expanding understanding of their emission characteristics.

Findings

Weak giant pulses form a separate intensity distribution

Detection of giant pulses at both main- and interpulse phases within one rotation

Analysis of scattering and scintillation properties of giant pulses

Abstract

The Crab pulsar is well-known for its anomalous giant radio pulse emission. Past studies have concentrated only on the very bright pulses or were insensitive to the faint end of the giant pulse luminosity distribution. With our new instrumentation offering a large bandwidth and high time resolution combined with the narrow radio beam of the Westerbork Synthesis Radio Telescope (WSRT), we seek to probe the weak giant pulse emission regime. The WSRT was used in a phased array mode, resolving a large fraction of the Crab nebula. The resulting pulsar signal was recorded using the PuMa II pulsar backend and then coherently dedispersed and searched for giant pulse emission. After careful flux calibration, the data were analysed to study the giant pulse properties. The analysis includes the distributions of the measured pulse widths, intensities, energies, and scattering times. The weak giant pulses are shown to form a separate part of the intensity distribution. The large number of giant pulses detected were used to analyse scattering and scintillation in giant pulses. We report for the first time the detection of giant pulse emission at both the main- and interpulse phases within a single rotation period. The rate of detection is consistent with the appearance of pulses at either pulse phase as being independent. These pulse pairs were used to examine the scintillation timescales within a single pulse period.