Cooling of the quasi-persistent neutron star X-ray transients KS 1731−260 and MXB 1659−29

We present Chandra and XMM–Newton X-ray observations that monitor the neutron star cooling of the quasi-persistent neutron star X-ray transients KS 1731−260 and MXB 1659−29 for approximately 4 yr after these sources returned to quiescence from prolonged outbursts. In both sources the outbursts were...

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Published in	Monthly notices of the Royal Astronomical Society Vol. 372; no. 1; pp. 479 - 488
Main Authors	Cackett, Edward M., Wijnands, Rudy, Linares, Manuel, Miller, Jon M., Homan, Jeroen, Lewin, Walter H. G.
Format	Journal Article
Language	English
Published	Oxford, UK Blackwell Publishing Ltd 11.10.2006 Blackwell Science Oxford University Press
Subjects	accretion accretion discs accretion, accretion discs Astronomy Earth, ocean, space Equilibrium Exact sciences and technology Spectrum analysis Stars & galaxies stars: neutron Temperature X-ray astronomy X-rays: binaries X-rays: individual: KS 1731−260 X-rays: individual: MXB 1659−29 X-rays: individual: MXB 1659−29 X-rays: individual: KS 1731−260 X-rays: binaries accretion, accretion discs stars: neutron Stellar cores Neutron stars X ray observation Atmosphere model Binary X ray source Cosmic x-ray sources Effective temperature Cool star X-ray spectra X-rays: individual: MXB 1659-29 Column density Star models Accretion disks Thermal equilibrium Quiescence Transient X ray source Flattening X-rays: individual: KS 1731 -260 X-ray binary stars Neutron monitors
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Abstract	We present Chandra and XMM–Newton X-ray observations that monitor the neutron star cooling of the quasi-persistent neutron star X-ray transients KS 1731−260 and MXB 1659−29 for approximately 4 yr after these sources returned to quiescence from prolonged outbursts. In both sources the outbursts were long enough to significantly heat the neutron star crust out of thermal equilibrium with the core. We analyse the X-ray spectra by fitting absorbed neutron star atmosphere models to the observations. The results of our analysis strengthen the preliminary findings of Wijnands et al. that in both sources the neutron star crust cools down very rapidly suggesting it has a high heat conductivity and that the neutron star core requires enhanced core cooling processes. Importantly, we now detect the flattening of the cooling in both sources as the crust returns to thermal equilibrium with the core. We measure the thermal equilbrium flux and temperature in both sources by fitting a curve that decays exponentially to a constant level. The cooling curves cannot be fit with just a simple exponential decay without the constant offset. We find the constant bolometric flux and effective temperature components to be (9.2 ± 0.9) × 10−14 erg cm−2 s−1 and 70.0 ± 1.6 eV in KS 1731−260 and (1.7 ± 0.3) × 10−14 erg cm−2 s−1 and 51.6 ± 1.4 eV in MXB 1659−29. We note that these values are dependent on the assumed distance to the sources and the column density which was tied between the observations due to the low number of photons in the latter observations. However, importantly, the shape of the cooling curves is independent of the distance assumed. In addition, we find that the crust of KS 1731−260 cools faster than that of MXB 1659−29 by a factor of ∼2, likely due to different crustal properties. This is the first time that the cooling of a neutron star crust into thermal equilibrium with the core has been observed in such detail.
AbstractList	We present Chandra and XMM–Newton X-ray observations that monitor the neutron star cooling of the quasi-persistent neutron star X-ray transients KS 1731−260 and MXB 1659−29 for approximately 4 yr after these sources returned to quiescence from prolonged outbursts. In both sources the outbursts were long enough to significantly heat the neutron star crust out of thermal equilibrium with the core. We analyse the X-ray spectra by fitting absorbed neutron star atmosphere models to the observations. The results of our analysis strengthen the preliminary findings of Wijnands et al. that in both sources the neutron star crust cools down very rapidly suggesting it has a high heat conductivity and that the neutron star core requires enhanced core cooling processes. Importantly, we now detect the flattening of the cooling in both sources as the crust returns to thermal equilibrium with the core. We measure the thermal equilbrium flux and temperature in both sources by fitting a curve that decays exponentially to a constant level. The cooling curves cannot be fit with just a simple exponential decay without the constant offset. We find the constant bolometric flux and effective temperature components to be (9.2 ± 0.9) × 10−14 erg cm−2 s−1 and 70.0 ± 1.6 eV in KS 1731−260 and (1.7 ± 0.3) × 10−14 erg cm−2 s−1 and 51.6 ± 1.4 eV in MXB 1659−29. We note that these values are dependent on the assumed distance to the sources and the column density which was tied between the observations due to the low number of photons in the latter observations. However, importantly, the shape of the cooling curves is independent of the distance assumed. In addition, we find that the crust of KS 1731−260 cools faster than that of MXB 1659−29 by a factor of ∼2, likely due to different crustal properties. This is the first time that the cooling of a neutron star crust into thermal equilibrium with the core has been observed in such detail. We present Chandra and XMM-Newton X-ray observations that monitor the neutron star cooling of the quasi-persistent neutron star X-ray transients KS 1731-260 and MXB 1659-29 for approximately 4 yr after these sources returned to quiescence from prolonged outbursts. In both sources the outbursts were long enough to significantly heat the neutron star crust out of thermal equilibrium with the core. We analyse the X-ray spectra by fitting absorbed neutron star atmosphere models to the observations. The results of our analysis strengthen the preliminary findings of Wijnands et al. that in both sources the neutron star crust cools down very rapidly suggesting it has a high heat conductivity and that the neutron star core requires enhanced core cooling processes. Importantly, we now detect the flattening of the cooling in both sources as the crust returns to thermal equilibrium with the core. We measure the thermal equilbrium flux and temperature in both sources by fitting a curve that decays exponentially to a constant level. The cooling curves cannot be fit with just a simple exponential decay without the constant offset. We find the constant bolometric flux and effective temperature components to be (9.2 +/- 0.9) x 10-14 erg cm-2 s-1 and 70.0 +/- 1.6 eV in KS 1731-260 and (1.7 +/- 0.3) x 10-14 erg cm-2 s-1 and 51.6 +/- 1.4 eV in MXB 1659-29. We note that these values are dependent on the assumed distance to the sources and the column density which was tied between the observations due to the low number of photons in the latter observations. However, importantly, the shape of the cooling curves is independent of the distance assumed. In addition, we find that the crust of KS 1731-260 cools faster than that of MXB 1659-29 by a factor of ~2, likely due to different crustal properties. This is the first time that the cooling of a neutron star crust into thermal equilibrium with the core has been observed in such detail. [PUBLICATION ABSTRACT] We present Chandra and XMM-Newton X-ray observations that monitor the neutron star cooling of the quasi-persistent neutron star X-ray transients KS 1731-260 and MXB 1659-29 for approximately 4 yr after these sources returned to quiescence from prolonged outbursts. In both sources the outbursts were long enough to significantly heat the neutron star crust out of thermal equilibrium with the core. We analyse the X-ray spectra by fitting absorbed neutron star atmosphere models to the observations. The results of our analysis strengthen the preliminary findings of Wijnands et al. that in both sources the neutron star crust cools down very rapidly suggesting it has a high heat conductivity and that the neutron star core requires enhanced core cooling processes. Importantly, we now detect the flattening of the cooling in both sources as the crust returns to thermal equilibrium with the core. We measure the thermal equilbrium flux and temperature in both sources by fitting a curve that decays exponentially to a constant level. The cooling curves cannot be fit with just a simple exponential decay without the constant offset. We find the constant bolometric flux and effective temperature components to be (9.2 plus/minus 0.9) x 10(-14)ergcm(-2) s(-1) and 70.0 plus/minus 1.6 eV in KS 1731-260 and (1.7 plus/minus 0.3) x 10(-14)ergcm(-2) s(-1) and 51.6 plus/minus 1.4 eV in MXB 1659-29. We note that these values are dependent on the assumed distance to the sources and the column density which was tied between the observations due to the low number of photons in the latter observations. However, importantly, the shape of the cooling curves is independent of the distance assumed. In addition, we find that the crust of KS 1731-260 cools faster than that of MXB 1659-29 by a factor of ~2, likely due to different crustal properties. This is the first time that the cooling of a neutron star crust into thermal equilibrium with the core has been observed in such detail. ABSTRACT We present Chandra and XMM–Newton X‐ray observations that monitor the neutron star cooling of the quasi‐persistent neutron star X‐ray transients KS 1731−260 and MXB 1659−29 for approximately 4 yr after these sources returned to quiescence from prolonged outbursts. In both sources the outbursts were long enough to significantly heat the neutron star crust out of thermal equilibrium with the core. We analyse the X‐ray spectra by fitting absorbed neutron star atmosphere models to the observations. The results of our analysis strengthen the preliminary findings of Wijnands et al. that in both sources the neutron star crust cools down very rapidly suggesting it has a high heat conductivity and that the neutron star core requires enhanced core cooling processes. Importantly, we now detect the flattening of the cooling in both sources as the crust returns to thermal equilibrium with the core. We measure the thermal equilbrium flux and temperature in both sources by fitting a curve that decays exponentially to a constant level. The cooling curves cannot be fit with just a simple exponential decay without the constant offset. We find the constant bolometric flux and effective temperature components to be (9.2 ± 0.9) × 10−14 erg cm−2 s−1 and 70.0 ± 1.6 eV in KS 1731−260 and (1.7 ± 0.3) × 10−14 erg cm−2 s−1 and 51.6 ± 1.4 eV in MXB 1659−29. We note that these values are dependent on the assumed distance to the sources and the column density which was tied between the observations due to the low number of photons in the latter observations. However, importantly, the shape of the cooling curves is independent of the distance assumed. In addition, we find that the crust of KS 1731−260 cools faster than that of MXB 1659−29 by a factor of ∼2, likely due to different crustal properties. This is the first time that the cooling of a neutron star crust into thermal equilibrium with the core has been observed in such detail.
Author	Homan, Jeroen Lewin, Walter H. G. Wijnands, Rudy Miller, Jon M. Linares, Manuel Cackett, Edward M.
Author_xml	– sequence: 1 givenname: Edward M. surname: Cackett fullname: Cackett, Edward M. email: emc14@st-andrews.ac.uk, emc14@st-andrews.ac.uk organization: School of Physics and Astronomy, University of St. Andrews, Fife KY16 9SS – sequence: 2 givenname: Rudy surname: Wijnands fullname: Wijnands, Rudy organization: Astronomical Institute ‘Anton Pannekoek’, University of Amsterdam, Kruislaan 403, 1098 SJ Amsterdam, the Netherlands – sequence: 3 givenname: Manuel surname: Linares fullname: Linares, Manuel organization: Astronomical Institute ‘Anton Pannekoek’, University of Amsterdam, Kruislaan 403, 1098 SJ Amsterdam, the Netherlands – sequence: 4 givenname: Jon M. surname: Miller fullname: Miller, Jon M. organization: University of Michigan, Department of Astronomy, 500 Church Street, Dennison 814, Ann Arbor, MI 48105, USA – sequence: 5 givenname: Jeroen surname: Homan fullname: Homan, Jeroen organization: MIT Kavli Institute for Astrophysics and Space Research, 77 Massachusetts Avenue, Cambridge, MA 02139, USA – sequence: 6 givenname: Walter H. G. surname: Lewin fullname: Lewin, Walter H. G. organization: MIT Kavli Institute for Astrophysics and Space Research, 77 Massachusetts Avenue, Cambridge, MA 02139, USA
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Keywords	X-rays: individual: MXB 1659−29 X-rays: individual: KS 1731−260 X-rays: binaries accretion, accretion discs stars: neutron Stellar cores Neutron stars X ray observation Atmosphere model Binary X ray source Cosmic x-ray sources Effective temperature Cool star X-ray spectra X-rays: individual: MXB 1659-29 Column density Star models Accretion disks Thermal equilibrium Quiescence Transient X ray source Flattening X-rays: individual: KS 1731 -260 X-ray binary stars Neutron monitors
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Snippet	We present Chandra and XMM–Newton X-ray observations that monitor the neutron star cooling of the quasi-persistent neutron star X-ray transients KS 1731−260... We present Chandra and XMM-Newton X-ray observations that monitor the neutron star cooling of the quasi-persistent neutron star X-ray transients KS 1731−260... ABSTRACT We present Chandra and XMM–Newton X‐ray observations that monitor the neutron star cooling of the quasi‐persistent neutron star X‐ray transients KS... We present Chandra and XMM-Newton X-ray observations that monitor the neutron star cooling of the quasi-persistent neutron star X-ray transients KS 1731-260...
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SubjectTerms	accretion accretion discs accretion, accretion discs Astronomy Earth, ocean, space Equilibrium Exact sciences and technology Spectrum analysis Stars & galaxies stars: neutron Temperature X-ray astronomy X-rays: binaries X-rays: individual: KS 1731−260 X-rays: individual: MXB 1659−29
Title	Cooling of the quasi-persistent neutron star X-ray transients KS 1731−260 and MXB 1659−29
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