Discovery of a Gamma-Ray Black Widow Pulsar by GPU-accelerated Einstein@Home

Nieder, L. and Clark, C. J. and Kandel, D. and Romani, R. W. and Bassa, C. G. and Allen, B. and Ashok, A. and Cognard, I. and Fehrmann, H. and Freire, P. and Karuppusamy, R. and Kramer, M. and Li, D. and Machenschalk, B. and Pan, Z. and Papa, M. A. and Ransom, S. M. and Ray, P. S. and Roy, J. and Wang, P. and Wu, J. and Aulbert, C. and Barr, E. D. and Beheshtipour, B. and Behnke, O. and Bhattacharyya, B. and Breton, R. P. and Camilo, F. and Choquet, C. and Dhillon, V. S. and Ferrara, E. C. and Guillemot, L. and Hessels, J. W. T. and Kerr, M. and Kwang, S. A. and Marsh, T. R. and Mickaliger, M. B. and Pleunis, Z. and Pletsch, H. J. and Roberts, M. S. E. and Sanpa-arsa, S. and Steltner, B. (2020) Discovery of a Gamma-Ray Black Widow Pulsar by GPU-accelerated Einstein@Home. The Astrophysical Journal Letters, 902 (2). L46. ISSN 2041-8205

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Abstract

We report the discovery of 1.97 ms period gamma-ray pulsations from the 75 minute orbital-period binary pulsar now named PSR J1653−0158. The associated Fermi Large Area Telescope gamma-ray source 4FGL J1653.6−0158 has long been expected to harbor a binary millisecond pulsar. Despite the pulsar-like gamma-ray spectrum and candidate optical/X-ray associations—whose periodic brightness modulations suggested an orbit—no radio pulsations had been found in many searches. The pulsar was discovered by directly searching the gamma-ray data using the GPU-accelerated Einstein@Home distributed volunteer computing system. The multidimensional parameter space was bounded by positional and orbital constraints obtained from the optical counterpart. More sensitive analyses of archival and new radio data using knowledge of the pulsar timing solution yield very stringent upper limits on radio emission. Any radio emission is thus either exceptionally weak, or eclipsed for a large fraction of the time. The pulsar has one of the three lowest inferred surface magnetic-field strengths of any known pulsar with Bsurf ≈ 4 × 107 G. The resulting mass function, combined with models of the companion star's optical light curve and spectra, suggests a pulsar mass ≳2 M⊙. The companion is lightweight with mass ∼0.01 M⊙, and the orbital period is the shortest known for any rotation-powered binary pulsar. This discovery demonstrates the Fermi Large Area Telescope's potential to discover extreme pulsars that would otherwise remain undetected.

Item Type: Article
Subjects: Grantha Library > Physics and Astronomy
Depositing User: Unnamed user with email support@granthalibrary.com
Date Deposited: 18 May 2023 07:03
Last Modified: 07 Sep 2024 10:21
URI: http://asian.universityeprint.com/id/eprint/953

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