Identifying pulsar candidates in interferometric radio images using scintillation

TL;DR

This paper introduces a novel method to identify pulsar candidates in interferometric radio images by detecting scintillation, enabling more efficient and targeted time-domain searches for elusive pulsars.

Contribution

The paper presents a new technique leveraging scintillation properties to select pulsar candidates, improving detection of challenging pulsars like sub-millisecond and highly-accelerated binary pulsars.

Findings

Successfully differentiates pulsars from non-scintillating sources

Extracted dynamic spectra match those from phased array observations

Demonstrated method on uGMRT data with real pulsar fields

Abstract

Pulsars have been primarily detected by their narrow pulses or periodicity in time domain data. Interferometric surveys for pulsars are challenging due to the trade-off between beam sensitivity and beam size and the corresponding tradeoff between survey sensitivity (depth), sky coverage, and computational efforts. The detection sensitivity of time-domain searches for pulsars is affected by dispersion smearing, scattering, and rapid orbital motion of pulsars in binaries. We have developed a new technique to select pulsar candidates in interferometric radio images by identifying scintillating sources and measuring their scintillation bandwidth and timescale. Identifying likely candidates allows sensitive, focused time-domain searches, saving computational effort. Pulsar scintillation is independent of its timing properties and hence offers a different selection of pulsars compared to time-domain searches. Candidates identified from this method could allow us to find hard-to-detect pulsars, such as sub-millisecond pulsars and pulsars in very compact, highly-accelerated binary orbits. We use uGMRT observations in the fields of PSR\,B1508+55, PSR\,J0437$-$4715, and PSR\,B0031$-$07 as test cases for our technique. We demonstrate that the technique correctly differentiates between the pulsar and other non-scintillating point sources and show that the extracted dynamic spectrum of the pulsar is equivalent to that extracted from the uGMRT phased array beam. We show the results from our analysis of known pulsar fields and discuss challenges in dealing with interference and instrumental effects.