The ONs and OFFs of Pulsar Radio Emission: Characterizing the Nulling Phenomenon

TL;DR

This paper introduces a new pulse summation method to more accurately measure nulling fractions in pulsars, especially weaker ones, and explores quasi-periodic nulling behavior across multiple pulsars.

Contribution

The paper presents the $ $sum algorithm, a novel method that improves nulling fraction measurement accuracy in noisy and limited data scenarios, and applies it to study nulling periodicity.

Findings

The $ $sum algorithm yields consistent nulling fraction measurements in weak pulsars.

First measurements of quasi-periodic nulling in five pulsars, including three new cases.

Analysis suggests a link between nulling behavior and spin-down energy loss.

Abstract

Radio emission from pulsars is known to exhibit a diverse range of emission phenomena, among which nulling, where the emission becomes temporarily undetectable, is an intriguing one. Observations suggest nulling is prevalent in many long-period pulsars and must be understood to obtain a more comprehensive picture of pulsar emission and its evolution. One of the limitations in observational characterisation of nulling is the limited signal-to-noise, making individual pulses often not easily distinguishable from noise or any putative faint emission. Although some of the approaches in the published literature attempt to address this, they lose efficacy when individual pulses appear indistinguishable from the noise, and as a result, can lead to less accurate measurements. Here we develop a new method (the $\mathbb{N}$sum algorithm) that uses sums of pulses for better distinguishability from noise and thus measures the nulling fraction more robustly. It can be employed for measuring nulling fractions in weaker pulsars and observations with a limited number of observed pulses. We compare our algorithm with the recently developed Gaussian Mixture Modelling approach, using both simulated and real data, and find that our approach yields consistent results for generic and weaker pulsars. We also explore quasi-periodicity in nulling and measure the related parameters for five pulsars, including PSRs~J1453$-$6413, J0950$+$0755 and J0026$-$1955, for which these are also the first such measurements. We compare and contrast our analysis of quasi-periodic nulling with previously published work and explore the use of spin-down energy loss ($\dot E$) to distinguish between different types of modulation behaviour.