4.7 Article

Improving pulsar-timing solutions through dynamic pulse fitting

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OXFORD UNIV PRESS
DOI: 10.1093/mnras/stad1660

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methods: data analysis; stars: neutron; pulsars: general; pulsars: individual: J1103-5403

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Precision pulsar timing is crucial for detecting nanohertz stochastic gravitational-wave background and understanding neutron star physics. The conventional method of fixed-time and frequency-averaged templates can lead to reduced accuracy due to the evolution of pulse shape over time. We propose a dynamic timing method that fits each observing epoch separately using basis functions, allowing for pulse shape evolution. Applying this method to PSR J1103-5403, we find evidence of mode changing and improve the timing solution by 1.78 times compared to template fitting. The reduction in white noise boosts the signal-to-noise ratio of gravitational-wave background signal by 32 percent for this pulsar.
Precision pulsar timing is integral to the detection of the nanohertz stochastic gravitational-wave background as well as understanding the physics of neutron stars. Conventional pulsar timing often uses fixed time and frequency-averaged templates to determine the pulse times of arrival, which can lead to reduced accuracy when the pulse profile evolves over time. We illustrate a dynamic timing method that fits each observing epoch using basis functions. By fitting each epoch separately, we allow for the evolution of the pulse shape epoch to epoch. We apply our method to PSR J1103-5403 and find evidence that it undergoes mode changing, making it the fourth millisecond pulsar to exhibit such behaviour. Our method, which is able to identify and time a single mode, yields a timing solution with a root-mean-square error of 1. 343 mu s, a factor of 1.78 improvement over template fitting on both modes. In addition, the white-noise amplitude is reduced 4.3 times, suggesting that fitting the full data set causes the mode changing to be incorrectly classified as white noise. This reduction in white noise boosts the signal-to-noise ratio of a gravitational-wave background signal for this particular pulsar by 32 per cent. We discuss the possible applications for this method of timing to study pulsar magnetospheres and further improve the sensitivity of searches for nanohertz gravitational waves.

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