The γ-ray Pulsar J0633+0632 in X-rays

Danilenko, A.; Shternin, P. S.; Карпова, А В; Zyuzin, D.; Shibanov, Yuriy

doi:10.1017/pasa.2015.40

Cited by 12 publications

(26 citation statements)

References 54 publications

(90 reference statements)

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“…We analysed the XMM-Newton observations of the J0633 γray pulsar. We confirmed previous investigations (Ray et al 2011;Danilenko et al 2015) that the pulsar spectrum contains thermal and non-thermal components. The former can be equally well fitted by either the blackbody or magnetized neutron star atmosphere models.…”

Section: Discussionsupporting

confidence: 92%

“…For these two models, our results are generally consistent with the results of that work, while the parameter uncertainties obtained here are much smaller. To our surprise, we found no evidence of the absorption spectral feature at 0.8 keV in the XMM-Newton data, whose presence in the Chandra data was claimed by Danilenko et al (2015). This becomes clear from examination of the residuals of the spectral fit by a purely continuum spectral model presented in Fig.…”

Section: Spectra Of J0633 and Its Pwnmentioning

confidence: 52%

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XMM–Newton observations of a gamma-ray pulsar J0633+0632: pulsations, cooling and large-scale emission

Danilenko

Карпова

Ofengeim

et al. 2020

Monthly Notices of the Royal Astronomical Society

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We report results of XMM-Newton observations of a γ-ray pulsar J0633+0632 and its wind nebula. We reveal, for the first time, pulsations of the pulsar X-ray emission with a single sinusoidal pulse-profile and a pulsed fraction of 23 ± 6 per cent in the 0.3-2 keV band. We confirm previous Chandra findings that the pulsar X-ray spectrum consists of thermal and non-thermal components. However, we do not find the absorption feature that was previously detected at about 0.8 keV. Thanks to the greater sensitivity of XMM-Newton, we get stronger constraints on spectral model parameters compared to previous studies. The thermal component can be equally well described by either blackbody or neutron star atmosphere models, implying that this emission is coming from either hot pulsar polar caps with a temperature of about 120 eV or from the colder bulk of the neutron star surface with a temperature of about 50 eV. In the latter case, the pulsar appears to be one of the coolest among other neutron stars of similar ages with estimated surface temperatures. We discuss cooling scenarios relevant to this neutron star. Using an interstellar absorption-distance relation, we also constrain the distance to the pulsar to the range of 0.7-2 kpc. Besides the pulsar and its compact nebula, we detect regions of weak large-scale diffuse non-thermal emission in the pulsar field and discuss their possible nature.

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Section: Discussionsupporting

confidence: 92%

Section: Spectra Of J0633 and Its Pwnmentioning

confidence: 52%

XMM–Newton observations of a gamma-ray pulsar J0633+0632: pulsations, cooling and large-scale emission

Danilenko

Карпова

Ofengeim

et al. 2020

Monthly Notices of the Royal Astronomical Society

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“…The general procedure is outlined e.g., in Section 2.1 of Danilenko et al (2015) and https://asd.gsfc.nasa.gov/ XSPECwiki/statistical_methods_in_XSPEC tended emission partially overlaps with one of MOS 1's damaged CCDs, and MOS2 has fewer net counts than the pn. Following the approach taken by, e.g., Younes et al (2016), we first extracted the background spectrum from the region shown by the dashed white circle in Figure 1.…”

Section: Spectral Analysismentioning

confidence: 99%

XMM-Newton and Chandra Observations of the Unidentified Fermi-LAT Source 3FGL J1016.5–6034: A Young Pulsar with a Nebula?

Hare

Volkov

Kargaltsev

et al. 2019

ApJ

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We report the discovery of a bright X-ray source in the XMM-Newton and Chandra X-ray Observatory (CXO) images of the unidentified Fermi-LAT source 3FGL J1016.5-6034. The XMM-Newton spectrum of the source is well fit by an absorbed blackbody+power-law model with a temperature, kT = 0.20 ± 0.02 keV, and photon index Γ = 1.8 ± 0.1. The CXO resolves the same source into a point source (CXOU J101546.0-602939) and a surrounding compact nebula seen up to about 30 from the point source. The CXO spectrum of the nebula can be described by an absorbed power-law with Γ = 1.7 ± 0.3 and is partly responsible for the non-thermal emission observed in the XMM-Newton spectrum. The XMM-Newton images also reveal faint extended emission on arcminute scales. These properties strongly suggest that the X-ray source and the accompanying extended emission are a newly discovered young pulsar with a pulsar wind nebula. We also analyze ∼ 10 years of Fermi-LAT data and find that the improved LAT source localization is consistent with the position of CXOU J101546.0-602939.We selected the unidentified source 3FGL J1016.5-6034 (hereafter J1016) from the Third Fermi-LAT Source Catalog (3FGL; Acero et al. 2015) to study in Xrays with the Chandra X-ray Observatory (CXO) and the X-ray Multi-Mirror Mission (XMM-Newton). According to the 3FGL catalog J1016 exhibits a pulsar-like spectrum at GeV energies (i.e., having significant spectral curvature and a soft photon index γ > 2.5) with a flux of f GeV = 2 × 10 −11 erg s −1 cm −2 in 0.1-100 GeV and lies relatively close to the Galactic plane (l = 285.0 • , b = −3.2 • ).Here we discuss CXO and XMM-Newton observations of J1016. In Section 2.1 we describe the observations and data reduction, in Sections 3 the CXO, XMM-Newton, and Fermi-LAT data analysis, followed by the discussion in Section 4 and summary of the results in Section 5. OBSERVATIONS AND DATA REDUCTION XMM-NewtonThe field of 3FGL J1016 was observed by XMM-Newton on 2017 May 25 for 18 ks (obsID 0802930101). The EPIC pn and both MOS detectors were operated in Full Frame mode, offering time resolutions of 73.4 ms and 2.6 s, respectively. We reduced and analyzed the XMM-Newton data using the Science Analysis System (SAS) version 16.1.0. Event lists for the pn, MOS1, and MOS2, were cleaned (e.g., removing times with high par-arXiv:1903.07651v1 [astro-ph.HE]

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“…Numbers 1 -41 enumerate the entries in Table 3 of Potekhin et al (2015). We have updated the data for object 4 according to Posselt et al (2013) and added objects 42 (XMMU J173203.3−344518, Klochkov et al 2015), 43 (CXOU J181852.0−150213, Klochkov et al 2016), and 44 (PSR J0633+0632, Danilenko et al 2015;Karpova et al 2017). The errorbars and arrows for magnetars are drawn in red color.…”

Section: Cooling Of Nonmagnetized Neutron Starsmentioning

confidence: 99%

“…For the thermal luminosity of the neutron star CXO J232327.9+584842 in the supernova remnant Cassiopeia A (object number 4, often dubbed Cas A NS) we have adopted improved observational data onL (Posselt et al 2013). We have supplemented this catalog with three neutron stars with recently measured thermal fluxes: two neutron stars with carbon envelopes (sources 42 and 43, Klochkov et al 2015Klochkov et al , 2016, and one pulsar (source 44, Danilenko et al 2015;Karpova et al 2017; in this case, we adopt the interpretation of the thermal spectrum with the model of a partially ionized magnetized hydrogen atmosphere nsmax, Ho et al 2008). Objects 25 through 41 (red symbols) are magnetars.…”

Section: Cooling Of Nonmagnetized Neutron Starsmentioning

confidence: 99%

Magnetic neutron star cooling and microphysics

Potekhin

Chabrier

2018

A&A

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Aims. We study the relative importance of several recent updates of microphysics input to the neutron star cooling theory and the effects brought about by superstrong magnetic fields of magnetars, including the effects of the Landau quantization in their crusts. Methods. We use a finite-difference code for simulation of neutron-star thermal evolution on timescales from hours to megayears with an updated microphysics input. The consideration of short timescales ( 1 yr) is made possible by a treatment of the heatblanketing envelope without the quasistationary approximation inherent to its treatment in traditional neutron-star cooling codes. For the strongly magnetized neutron stars, we take into account the effects of Landau quantization on thermodynamic functions and thermal conductivities. We simulate cooling of ordinary neutron stars and magnetars with non-accreted and accreted crusts and compare the results with observations. Results. Suppression of radiative and conductive opacities in strongly quantizing magnetic fields and formation of a condensed radiating surface substantially enhance the photon luminosity at early ages, making the life of magnetars brighter but shorter. These effects together with the effect of strong proton superfluidity, which slows down the cooling of kiloyear-aged neutron stars, can explain thermal luminosities of about a half of magnetars without invoking heating mechanisms. Observed thermal luminosities of other magnetars are still higher than theoretical predictions, which implies heating, but the effects of quantizing magnetic fields and baryon superfluidity help to reduce the discrepancy.

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The γ-ray Pulsar J0633+0632 in X-rays

Cited by 12 publications

References 54 publications

XMM–Newton observations of a gamma-ray pulsar J0633+0632: pulsations, cooling and large-scale emission

XMM–Newton observations of a gamma-ray pulsar J0633+0632: pulsations, cooling and large-scale emission

XMM-Newton and Chandra Observations of the Unidentified Fermi-LAT Source 3FGL J1016.5–6034: A Young Pulsar with a Nebula?

Magnetic neutron star cooling and microphysics

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