A NICER View of the Massive Pulsar PSR J0740+6620 Informed by Radio Timing and XMM-Newton Spectroscopy

Creators: Riley, Thomas E.; Watts, Anna L.; Ray, Paul S.; Bogdanov, Slavko; Guillot, Sebastien; Morsink, Sharon M.; Bilous, Anna V.; Arzoumanian, Zaven; Choudhury, Devarshi; Deneva, Julia S.; Gendreau, Keith C.; Harding, Alice K.; Ho, Wynn C. G.; Lattimer, James M.; Loewenstein, Michael; Ludlam, Renee M.; Markwardt, Craig B.; Okajima, Takashi; Prescod-Weinstein, Chanda; Remillard, Ronald A.; Wolff, Michael T.; Fonseca, Emmanuel; Cromartie, H. Thankful; Kerr, Matthew; Pennucci, Timothy T.; Parthasarathy, Aditya; Ransom, Scott; Stairs, Ingrid; Guillemot, Lucas; Cognard, Ismael

Abstract

We report on Bayesian estimation of the radius, mass, and hot surface regions of the massive millisecond pulsar PSR J0740+6620, conditional on pulse-profile modeling of Neutron Star Interior Composition Explorer X-ray Timing Instrument event data. We condition on informative pulsar mass, distance, and orbital inclination priors derived from the joint North American Nanohertz Observatory for Gravitational Waves and Canadian Hydrogen Intensity Mapping Experiment/Pulsar wideband radio timing measurements of Fonseca et al. We use XMM-Newton European Photon Imaging Camera spectroscopic event data to inform our X-ray likelihood function. The prior support of the pulsar radius is truncated at 16 km to ensure coverage of current dense matter models. We assume conservative priors on instrument calibration uncertainty. We constrain the equatorial radius and mass of PSR J0740+6620 to be 12.39_(-0.98)^(+1.30) km and 2.072_(-0.066)}^(+0.067) M_⊙ respectively, each reported as the posterior credible interval bounded by the 16% and 84% quantiles, conditional on surface hot regions that are non-overlapping spherical caps of fully ionized hydrogen atmosphere with uniform effective temperature; a posteriori, the temperature is log₁₀(T[K] = 5.99_(-0.06)^(+0.05) for each hot region. All software for the X-ray modeling framework is open-source and all data, model, and sample information is publicly available, including analysis notebooks and model modules in the Python language. Our marginal likelihood function of mass and equatorial radius is proportional to the marginal joint posterior density of those parameters (within the prior support) and can thus be computed from the posterior samples.

Additional Information

© 2021. The American Astronomical Society. Received 2021 April 16; revised 2021 June 9; accepted 2021 June 9; published 2021 September 8. This work was supported in part by NASA through the NICER mission and the Astrophysics Explorers Program. T.E.R. and A.L.W. acknowledge support from ERC Consolidator grant No. 865768 AEONS (PI: Watts). T.E.R. also acknowledges support from the Nederlandse Organisatie voor Wetenschappelijk Onderzoek (NWO) through the VIDI and Projectruimte grants (PI: Nissanke). This work was sponsored by NWO Exact and Natural Sciences for the use of supercomputer facilities, and was carried out on the Dutch national e-infrastructure with the support of SURF Cooperative. This work was granted access to the HPC resources of CALMIP supercomputing center under the allocation 2016- P19056. S.B. was funded in part by NASA grants NNX17AC28G and 80NSSC20K0275. S.M.M. thanks NSERC for support. W.C.G.H. appreciates use of computer facilities at the Kavli Institute for Particle Astrophysics and Cosmology and acknowledges support through grant 80NSSC20K0278 from NASA. R.M.L. acknowledges the support of NASA through Hubble Fellowship Program grant HST-HF2-51440.001. Support for H.T.C. was provided by NASA through the NASA Hubble Fellowship Program grant #HST-HF2-51453.001 awarded by the Space Telescope Science Institute, which is operated by the Association of Universities for Research in Astronomy, Inc., for NASA, under contract NAS5-26555. T.T.P. is a NANOGrav Physics Frontiers Center Postdoctoral Fellow funded by the National Science Foundation award number 1430284. The National Radio Astronomy Observatory is a facility of the National Science Foundation operated under cooperative agreement by Associated Universities, Inc. S.M.R. is a CIFAR Fellow and is supported by the NSF Physics Frontiers Center award 1430284. Pulsar research at UBC is supported by an NSERC Discovery Grant and by the Canadian Institute for Advanced Research. This research has made extensive use of NASA's Astrophysics Data System Bibliographic Services (ADS) and the arXiv. We would also like to acknowledge the administrative and facilities staff whose labor supports our work. Facility: N - ICER XTI (Gendreau et al. 2016), NANOGrav, Green Bank Telescope, CHIME/Pulsar, XMM-Newton EPIC. Software: Python/C language (Oliphant 2007), GNU Scientific Library (GSL; Gough 2009), NumPy (van der Walt et al. 2011), Cython (Behnel et al. 2011), SciPy (Jones et al. 2001), OpenMP (Dagum & Menon 1998), MPI (Forum 1994), MPI for Python (Dalcín et al. 2008), Matplotlib (Hunter 2007; Droettboom et al. 2018), IPython (Perez & Granger 2007), Jupyter (Kluyver et al. 2016), tempo2 (photons; Hobbs et al. 2006), PINT (photonphase; https://github.com/nanograv/PINT), MultiNest (Feroz et al. 2009), PyMultiNest (Buchner et al. 2014), GetDist (Lewis 2019, https://github.com/cmbant/getdist), nestcheck (Higson 2018; Higson et al. 2018, 2019), fgivenx (Handley 2018), NICERsoft (https://github.com/paulray/NICERsoft), X-PSIv0.7 (https://github.com/ThomasEdwardRiley/xpsi; Riley 2021).

Attached Files

Published - Riley_2021_ApJL_918_L27.pdf

Files

Riley_2021_ApJL_918_L27.pdf

Files (18.6 MB)

Name	Size	Download all
Riley_2021_ApJL_918_L27.pdf md5:9c547298f89e31aed38238b1c6476e16	18.6 MB	Preview Download

Additional details

	All versions	This version
Views	0	0
Downloads	0	0
Data volume	0 Bytes	0 Bytes