TY - JOUR
T1 - Stellar multiplicity and stellar rotation:
T2 - Insights from APOGEE
AU - Daher, Christine Mazzola
AU - Badenes, Carles
AU - Tayar, Jamie
AU - Pinsonneault, Marc
AU - Koposov, Sergey E.
AU - Kratter, Kaitlin
AU - Moe, Maxwell
AU - Anguiano, Borja
AU - Godoy-Rivera, Diego
AU - Majewski, Steven
AU - Carlberg, Joleen K.
AU - Walker, Matthew G.
AU - Buttry, Rachel
AU - Dixon, Don
AU - Serna, Javier
AU - Stassun, Keivan G.
AU - Lee, Nathan De
AU - Hernández, Jesús
AU - Nitschelm, Christian
AU - Stringfellow, Guy S.
AU - Troup, Nicholas W.
N1 - 12 pages, 9 figures; accepted by MNRAS
Funding Information:
National Science Foundation (NSF) grant AST-1909022
Publisher Copyright:
© 2022 The Author(s) Published by Oxford University Press on behalf of Royal Astronomical Society.
PY - 2022/5/1
Y1 - 2022/5/1
N2 - We measure rotational broadening in spectra taken by the Apache Point
Observatory Galactic Evolution Experiment (APOGEE) survey to
characterise the relationship between stellar multiplicity and rotation.
We create a sample of 2786 giants and 24 496 dwarfs with stellar
parameters and multiple radial velocities from the APOGEE pipeline,
projected rotation speeds vsin i determined from our
own pipeline, and distances, masses, and ages measured by Sanders &
Das. We use the statistical distribution of the maximum shift in the
radial velocities, ΔRVmax, as a proxy for the close binary
fraction to explore the interplay between stellar evolution, rotation,
and multiplicity. Assuming that the minimum orbital period allowed is
the critical period for Roche Lobe overflow and rotational
synchronization, we calculate theoretical upper limits on expected vsin i and ΔRVmax values. These expectations agree with the positive correlation between the maximum ΔRVmax and vsin i values observed in our sample as a function of log (g). We find that the fast rotators in our sample have a high occurrence of short-period (log (P/d)
≲ 4) companions. We also find that old, rapidly-rotating main sequence
stars have larger completeness-corrected close binary fractions than
their younger peers. Furthermore, rapidly-rotating stars with large ΔRVmax
consistently show differences of 1-10 Gyr between the predicted
gyrochronological and measured isochronal ages. These results point
towards a link between rapid rotation and close binarity through tidal
interactions. We conclude that stellar rotation is strongly correlated
with stellar multiplicity in the field, and caution should be taken in
the application of gyrochronology relations to cool stars.
AB - We measure rotational broadening in spectra taken by the Apache Point
Observatory Galactic Evolution Experiment (APOGEE) survey to
characterise the relationship between stellar multiplicity and rotation.
We create a sample of 2786 giants and 24 496 dwarfs with stellar
parameters and multiple radial velocities from the APOGEE pipeline,
projected rotation speeds vsin i determined from our
own pipeline, and distances, masses, and ages measured by Sanders &
Das. We use the statistical distribution of the maximum shift in the
radial velocities, ΔRVmax, as a proxy for the close binary
fraction to explore the interplay between stellar evolution, rotation,
and multiplicity. Assuming that the minimum orbital period allowed is
the critical period for Roche Lobe overflow and rotational
synchronization, we calculate theoretical upper limits on expected vsin i and ΔRVmax values. These expectations agree with the positive correlation between the maximum ΔRVmax and vsin i values observed in our sample as a function of log (g). We find that the fast rotators in our sample have a high occurrence of short-period (log (P/d)
≲ 4) companions. We also find that old, rapidly-rotating main sequence
stars have larger completeness-corrected close binary fractions than
their younger peers. Furthermore, rapidly-rotating stars with large ΔRVmax
consistently show differences of 1-10 Gyr between the predicted
gyrochronological and measured isochronal ages. These results point
towards a link between rapid rotation and close binarity through tidal
interactions. We conclude that stellar rotation is strongly correlated
with stellar multiplicity in the field, and caution should be taken in
the application of gyrochronology relations to cool stars.
KW - Binaries: Close
KW - Binaries: Spectroscopic
KW - Stars: Evolution
KW - Stars: Rotation
U2 - 10.1093/mnras/stac590
DO - 10.1093/mnras/stac590
M3 - Article
SN - 0035-8711
VL - 512
SP - 2051
EP - 2061
JO - Monthly Notices of the Royal Astronomical Society
JF - Monthly Notices of the Royal Astronomical Society
IS - 2
ER -