Accurate Ray-tracing of Realistic Neutron Star Atmospheres for Constraining Their Parameters

Vincent, F.; Bejger, M.; Różáńska, A.; Straub, O.; Paumard, T.; Fortin, M.; Madej, J.; Majczyna, A.; Gourgoulhon, Éric; Haensel, P.; Zdunik, J. L.; Beldycki, B.

doi:10.3847/1538-4357/aab0a3

Cited by 20 publications

(18 citation statements)

References 52 publications

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“…This is in agreement with the more general analysis of Raposo et al (2019), who showed that even ultracompact stars are possible when larger anisotropic pressures take place. An interesting consequence for systems with ∂M/∂ρ c < 0 is that they could be more compact, which could lead to a richer phenomenology that may be probed with electromagnetic missions and relativistic ray-tracing models (see, e.g., Vincent et al 2018;Raaijmakers et al 2019).…”

Section: Discussionmentioning

confidence: 99%

Probing Elastic Quark Phases in Hybrid Stars with Radius Measurements

Pereira

Bejger

Tonetto

et al. 2021

ApJ

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The internal composition of neutron stars is currently largely unknown. Due to the possibility of phase transitions in quantum chromodynamics, stars could be hybrid and have quark cores. We investigate some imprints of elastic quark phases (only when perturbed) on the dynamical stability of hybrid stars. We show that they increase the dynamical stability window of hybrid stars in the sense that the onset of instabilities happens at larger central densities than the ones for maximum masses. In particular, when the shear modulus of a crystalline quark phase is taken at face value, the relative radius differences between elastic and perfect-fluid hybrid stars with null radial frequencies (onset of instability) would be up to 1%-2%. Roughly, this would imply a maximum relative radius dispersion (on top of the perfect-fluid predictions) of 2%-4% for stars in a given mass range exclusively due to the elasticity of the quark phase. In the more agnostic approach where the estimates for the quark shear modulus only suggest its possible order of magnitude (due to the many approximations taken in its calculation), the relative radius dispersion uniquely due to a quark phase elasticity might be as large as 5%-10%. Finally, we discuss possible implications of the above dispersion of radii for the constraint of the elasticity of a quark phase with electromagnetic missions such as NICER, eXTP, and ATHENA.Unified Astronomy Thesaurus concepts: General relativity (641); Neutron stars (1108); Stellar oscillations (1617)

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Section: Discussionmentioning

confidence: 99%

Probing Elastic Quark Phases in Hybrid Stars with Radius Measurements

Pereira

Bejger

Tonetto

et al. 2021

ApJ

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“…A rotating NS is not perfectly spherical and the spacetime external to the star is not exactly Schwarzschild. If we wished to compute the waveforms from rotating hot spots with the greatest possible accuracy and precision, we would therefore have to solve the exact general relativistic equations for the stellar shape and exterior spacetime metric using an axisymmetric code such as RNS (Stergioulas & Friedman 1995) or LORENE/NROTSTAR (Vincent et al 2018) and then trace the rays in that spacetime.…”

Section: Modeling Hot Spot Emission From Neutron Stars In the S+d Appmentioning

confidence: 99%

Constraining the Neutron Star Mass–Radius Relation and Dense Matter Equation of State with NICER. II. Emission from Hot Spots on a Rapidly Rotating Neutron Star

Bogdanov

Lamb

Mahmoodifar

et al. 2019

ApJL

144

133

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We describe the model of surface emission from a rapidly rotating neutron star that is applied to Neutron Star Interior Composition Explorer X-ray data of millisecond pulsars in order to statistically constrain the neutron star mass-radius relation and dense matter equation of state. To ensure that the associated calculations are both accurate and precise, we conduct an extensive suite of verification tests between our numerical codes for both the Schwarzschild + Doppler and Oblate Schwarzschild approximations, and compare both approximations against exact numerical calculations. We find superb agreement between the code outputs, as well as in comparison against a set of analytical and semianalytical calculations, which combined with their speed, demonstrates that the codes are well-suited for large-scale statistical sampling applications. A set of verified, high-precision reference synthetic pulse profiles is provided to the community to facilitate testing of other independently developed codes.

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“…As the star spins, the flux and spectrum of X-ray emission registered by a distant observer is modulated in a periodic manner: we can determine the rotational phase evolution of pulsars precisely and build up a pulse profile (X-ray counts per rotational phase bin per detector channel) by phase-folding X-ray events according to an ephemeris. 23 The mapping of surface emission into the pulse profile detected by a distant observer, via relativistic ray-tracing through the spacetime of a rapidly rotating (and hence oblate) star, is well understood (Pechenick et al 1983;Miller & Lamb 1998;Poutanen & Gierliński 2003;Poutanen & Beloborodov 2006;Cadeau et al 2007;Morsink et al 2007;Bauböck et al 2013;AlGendy & Morsink 2014;Nättilä & Pihajoki 2018;Vincent et al 2018). Thus, given a model for the surface emission (e.g., a geometrically thin atmosphere of some chemical and ionic composition together with a local comoving effective temperature field as a function of surface coordinates), one calculates the expected pulse profile for a given exterior spacetime solution and a given instrument.…”

Section: Introductionmentioning

confidence: 99%

A NICER View of PSR J0030+0451: Millisecond Pulsar Parameter Estimation

Riley

Watts

Bogdanov

et al. 2019

ApJL

1,397

109

1,295

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We report on Bayesian parameter estimation of the mass and equatorial radius of the millisecond pulsar PSRJ0030 +0451, conditional on pulse-profile modeling of Neutron Star Interior Composition Explorer X-ray spectraltiming event data. We perform relativistic ray-tracing of thermal emission from hot regions of the pulsar's surface. We assume two distinct hot regions based on two clear pulsed components in the phase-folded pulse-profile data; we explore a number of forms (morphologies and topologies) for each hot region, inferring their parameters in addition to the stellar mass and radius. For the family of models considered, the evidence (prior predictive probability of the data) strongly favors a model that permits both hot regions to be located in the same rotational hemisphere. Models wherein both hot regions are assumed to be simply connected circular single-temperature spots, in particular those where the spots are assumed to be reflection-symmetric with respect to the stellar origin, are strongly disfavored. For the inferred configuration, one hot region subtends an angular extent of only a few degrees (in spherical coordinates with origin at the stellar center) and we are insensitive to other structural details; the second hot region is far more azimuthally extended in the form of a narrow arc, thus requiring a larger number of parameters to describe. The inferred mass M and equatorial radius R eq are, respectively,-+ eq 2 0.010 0.008 is more tightly constrained; the credible interval bounds reported here are approximately the 16% and 84% quantiles in marginal posterior mass.

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Accurate Ray-tracing of Realistic Neutron Star Atmospheres for Constraining Their Parameters

Cited by 20 publications

References 52 publications

Probing Elastic Quark Phases in Hybrid Stars with Radius Measurements

Probing Elastic Quark Phases in Hybrid Stars with Radius Measurements

Constraining the Neutron Star Mass–Radius Relation and Dense Matter Equation of State with NICER. II. Emission from Hot Spots on a Rapidly Rotating Neutron Star

A NICER View of PSR J0030+0451: Millisecond Pulsar Parameter Estimation

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