Asteroseismology and Gaia:: Testing Scaling Relations Using 2200 Kepler Stars with TGAS Parallaxes

Daniel Huber; Joel Zinn; Mathias Bojsen-hansen; Marc Pinsonneault; Christian Sahlholdt; Aldo Serenelli; Victor Silva Aguirre; Keivan Stassun; Dennis Stello; Jamie Tayar; Fabienne Bastien; Timothy R. Bedding; Lars A. Buchhave; William J. Chaplin; Guy R. Davies; Rafael A. García; David W. Latham; Savita Mathur; Benoit Mosser; Sanjib Sharma

doi:10.3847/1538-4357/aa75ca

Asteroseismology and Gaia: Testing Scaling Relations Using 2200 Kepler Stars with TGAS Parallaxes

Daniel Huber, Joel Zinn, Mathias Bojsen-hansen, Marc Pinsonneault, Christian Sahlholdt, Aldo Serenelli, Victor Silva Aguirre, Keivan Stassun, Dennis Stello, Jamie Tayar, Fabienne Bastien, Timothy R. Bedding, Lars A. Buchhave, William J. Chaplin, Guy R. Davies, Rafael A. García, David W. Latham, Savita Mathur, Benoit Mosser, Sanjib Sharma

Physics and Astronomy

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Abstract

We present a comparison of parallaxes and radii from asteroseismology and Gaia DR1 (TGAS) for 2200 Kepler stars spanning from the main sequence to the red-giant branch. We show that previously identified offsets between TGAS parallaxes and distances derived from asteroseismology and eclipsing binaries have likely been overestimated for parallaxes mas (≈90%–98% of the TGAS sample). The observed differences in our sample can furthermore be partially compensated by adopting a hotter scale (such as the infrared flux method) instead of spectroscopic temperatures for dwarfs and subgiants. Residual systematic differences are at the ≈2% level in parallax across three orders of magnitude. We use TGAS parallaxes to empirically demonstrate that asteroseismic radii are accurate to ≈5% or better for stars between . We find no significant offset for main-sequence () and low-luminosity RGB stars (≈3–8 ), but seismic radii appear to be systematically underestimated by ≈5% for subgiants (≈1.5–3 ). We find no systematic errors as a function of metallicity between to dex, and show tentative evidence that corrections to the scaling relation for the large frequency separation () improve the agreement with TGAS for RGB stars. Finally, we demonstrate that beyond asteroseismology will provide more precise distances than end-of-mission Gaia data, highlighting the synergy and complementary nature of Gaia and asteroseismology for studying galactic stellar populations.

Original language	English
Pages (from-to)	102
Journal	The Astrophysical Journal
Volume	844
Issue number	102
Early online date	27 Jul 2017
DOIs	https://doi.org/10.3847/1538-4357/aa75ca
Publication status	E-pub ahead of print - 27 Jul 2017

Keywords

parallaxes
stars: distances
stars: fundamental parameters
stars: late-type
stars: oscillations
techniques: photometric

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Asteroseismology and Helioseismology at Birmingham and Queen Mary
Chaplin, B., Elsworth, Y. & Miglio, A.
SCIENCE & TECHNOLOGY FACILITIES COUNCIL
1/04/15 → 30/09/18
Project: Research Councils

Cite this

Huber, D., Zinn, J., Bojsen-hansen, M., Pinsonneault, M., Sahlholdt, C., Serenelli, A., Aguirre, V. S., Stassun, K., Stello, D., Tayar, J., Bastien, F., Bedding, T. R., Buchhave, L. A., Chaplin, W. J., Davies, G. R., García, R. A., Latham, D. W., Mathur, S., Mosser, B., & Sharma, S. (2017). Asteroseismology and Gaia: Testing Scaling Relations Using 2200 Kepler Stars with TGAS Parallaxes. The Astrophysical Journal, 844(102), 102. Advance online publication. https://doi.org/10.3847/1538-4357/aa75ca

@article{d9342f2aa81d4a52acefd51e7e01479f,

title = "Asteroseismology and Gaia:: Testing Scaling Relations Using 2200 Kepler Stars with TGAS Parallaxes",

abstract = "We present a comparison of parallaxes and radii from asteroseismology and Gaia DR1 (TGAS) for 2200 Kepler stars spanning from the main sequence to the red-giant branch. We show that previously identified offsets between TGAS parallaxes and distances derived from asteroseismology and eclipsing binaries have likely been overestimated for parallaxes mas (≈90%–98% of the TGAS sample). The observed differences in our sample can furthermore be partially compensated by adopting a hotter scale (such as the infrared flux method) instead of spectroscopic temperatures for dwarfs and subgiants. Residual systematic differences are at the ≈2% level in parallax across three orders of magnitude. We use TGAS parallaxes to empirically demonstrate that asteroseismic radii are accurate to ≈5% or better for stars between . We find no significant offset for main-sequence () and low-luminosity RGB stars (≈3–8 ), but seismic radii appear to be systematically underestimated by ≈5% for subgiants (≈1.5–3 ). We find no systematic errors as a function of metallicity between to dex, and show tentative evidence that corrections to the scaling relation for the large frequency separation () improve the agreement with TGAS for RGB stars. Finally, we demonstrate that beyond asteroseismology will provide more precise distances than end-of-mission Gaia data, highlighting the synergy and complementary nature of Gaia and asteroseismology for studying galactic stellar populations.",

keywords = "parallaxes , stars: distances , stars: fundamental parameters , stars: late-type , stars: oscillations , techniques: photometric",

author = "Daniel Huber and Joel Zinn and Mathias Bojsen-hansen and Marc Pinsonneault and Christian Sahlholdt and Aldo Serenelli and Aguirre, {Victor Silva} and Keivan Stassun and Dennis Stello and Jamie Tayar and Fabienne Bastien and Bedding, {Timothy R.} and Buchhave, {Lars A.} and Chaplin, {William J.} and Davies, {Guy R.} and Garc{\'i}a, {Rafael A.} and Latham, {David W.} and Savita Mathur and Benoit Mosser and Sanjib Sharma",

year = "2017",

month = jul,

day = "27",

doi = "10.3847/1538-4357/aa75ca",

language = "English",

volume = "844",

pages = "102",

journal = "The Astrophysical Journal",

issn = "0004-637X",

publisher = "Institute of Physics Publishing Ltd",

number = "102",

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Huber, D, Zinn, J, Bojsen-hansen, M, Pinsonneault, M, Sahlholdt, C, Serenelli, A, Aguirre, VS, Stassun, K, Stello, D, Tayar, J, Bastien, F, Bedding, TR, Buchhave, LA, Chaplin, WJ , Davies, GR, García, RA, Latham, DW, Mathur, S, Mosser, B & Sharma, S 2017, 'Asteroseismology and Gaia: Testing Scaling Relations Using 2200 Kepler Stars with TGAS Parallaxes', The Astrophysical Journal, vol. 844, no. 102, pp. 102. https://doi.org/10.3847/1538-4357/aa75ca

TY - JOUR

T1 - Asteroseismology and Gaia:

T2 - Testing Scaling Relations Using 2200 Kepler Stars with TGAS Parallaxes

AU - Huber, Daniel

AU - Zinn, Joel

AU - Bojsen-hansen, Mathias

AU - Pinsonneault, Marc

AU - Sahlholdt, Christian

AU - Serenelli, Aldo

AU - Aguirre, Victor Silva

AU - Stassun, Keivan

AU - Stello, Dennis

AU - Tayar, Jamie

AU - Bastien, Fabienne

AU - Bedding, Timothy R.

AU - Buchhave, Lars A.

AU - Chaplin, William J.

AU - Davies, Guy R.

AU - García, Rafael A.

AU - Latham, David W.

AU - Mathur, Savita

AU - Mosser, Benoit

AU - Sharma, Sanjib

PY - 2017/7/27

Y1 - 2017/7/27

N2 - We present a comparison of parallaxes and radii from asteroseismology and Gaia DR1 (TGAS) for 2200 Kepler stars spanning from the main sequence to the red-giant branch. We show that previously identified offsets between TGAS parallaxes and distances derived from asteroseismology and eclipsing binaries have likely been overestimated for parallaxes mas (≈90%–98% of the TGAS sample). The observed differences in our sample can furthermore be partially compensated by adopting a hotter scale (such as the infrared flux method) instead of spectroscopic temperatures for dwarfs and subgiants. Residual systematic differences are at the ≈2% level in parallax across three orders of magnitude. We use TGAS parallaxes to empirically demonstrate that asteroseismic radii are accurate to ≈5% or better for stars between . We find no significant offset for main-sequence () and low-luminosity RGB stars (≈3–8 ), but seismic radii appear to be systematically underestimated by ≈5% for subgiants (≈1.5–3 ). We find no systematic errors as a function of metallicity between to dex, and show tentative evidence that corrections to the scaling relation for the large frequency separation () improve the agreement with TGAS for RGB stars. Finally, we demonstrate that beyond asteroseismology will provide more precise distances than end-of-mission Gaia data, highlighting the synergy and complementary nature of Gaia and asteroseismology for studying galactic stellar populations.

AB - We present a comparison of parallaxes and radii from asteroseismology and Gaia DR1 (TGAS) for 2200 Kepler stars spanning from the main sequence to the red-giant branch. We show that previously identified offsets between TGAS parallaxes and distances derived from asteroseismology and eclipsing binaries have likely been overestimated for parallaxes mas (≈90%–98% of the TGAS sample). The observed differences in our sample can furthermore be partially compensated by adopting a hotter scale (such as the infrared flux method) instead of spectroscopic temperatures for dwarfs and subgiants. Residual systematic differences are at the ≈2% level in parallax across three orders of magnitude. We use TGAS parallaxes to empirically demonstrate that asteroseismic radii are accurate to ≈5% or better for stars between . We find no significant offset for main-sequence () and low-luminosity RGB stars (≈3–8 ), but seismic radii appear to be systematically underestimated by ≈5% for subgiants (≈1.5–3 ). We find no systematic errors as a function of metallicity between to dex, and show tentative evidence that corrections to the scaling relation for the large frequency separation () improve the agreement with TGAS for RGB stars. Finally, we demonstrate that beyond asteroseismology will provide more precise distances than end-of-mission Gaia data, highlighting the synergy and complementary nature of Gaia and asteroseismology for studying galactic stellar populations.

KW - parallaxes

KW - stars: distances

KW - stars: fundamental parameters

KW - stars: late-type

KW - stars: oscillations

KW - techniques: photometric

U2 - 10.3847/1538-4357/aa75ca

DO - 10.3847/1538-4357/aa75ca

M3 - Article

SN - 0004-637X

VL - 844

SP - 102

JO - The Astrophysical Journal

JF - The Astrophysical Journal

IS - 102

ER -

Asteroseismology and Gaia: Testing Scaling Relations Using 2200 Kepler Stars with TGAS Parallaxes

Abstract

Keywords

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Asteroseismology and Helioseismology at Birmingham and Queen Mary

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