ARMADA I: Triple Companions Detected in B-Type Binaries alpha Del and nu   Gem

Tyler Gardner (1); John D. Monnier (1); Francis C. Fekel (2); Gail; Schaefer (3); Keith J.C. Johnson (1); Jean-Baptiste Le Bouquin (4); Stefan; Kraus (5); Narsireddy Anugu (6); Benjamin R. Setterholm (1); Aaron Labdon; (5); Claire L. Davies (5); Cyprien Lanthermann (7); Jacob Ennis (1); Michael; Ireland (8); Kaitlin M. Kratter (6); Theo Ten Brummelaar (3); Judit Sturmann; (3); Laszlo Sturmann (3); Chris Farrington (3); Douglas R. Gies (3); Robert; Klement (3); Fred C. Adams (1) ((1) University of Michigan; Ann Arbor; (2); Tennessee State University; (3) The CHARA Array of Georgia State University,; (4) Institut de Planetologie et d'Astrophysique de Grenoble; (5) University; of Exeter; (6) University of Arizona; (7) KU Leuven; (8) Australian National; University)

arXiv:2012.00778·astro-ph.SR·January 6, 2021

ARMADA I: Triple Companions Detected in B-Type Binaries alpha Del and nu Gem

Tyler Gardner (1), John D. Monnier (1), Francis C. Fekel (2), Gail, Schaefer (3), Keith J.C. Johnson (1), Jean-Baptiste Le Bouquin (4), Stefan, Kraus (5), Narsireddy Anugu (6), Benjamin R. Setterholm (1), Aaron Labdon, (5), Claire L. Davies (5), Cyprien Lanthermann (7)

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TL;DR

The ARMADA survey uses high-precision interferometry to detect and characterize tertiary companions in B-type binary systems, revealing new triple systems and refining orbital parameters.

Contribution

This study introduces a high-precision interferometric method for detecting short-period companions in binary systems, achieving tenfold improvement over previous surveys.

Findings

01

Detected tertiary companions in alpha Del and nu Gem binaries.

02

Measured orbits and masses of all three components in these systems.

03

Identified inconsistency in previous RV orbit for nu Gem.

Abstract

Ground-based optical long-baseline interferometry has the power to measure the orbits of close binary systems at ~10 micro-arcsecond precision. This precision makes it possible to detect "wobbles" in the binary motion due to the gravitational pull from additional short period companions. We started the ARrangement for Micro-Arcsecond Differential Astrometry (ARMADA) survey with the MIRC-X instrument at the CHARA array for the purpose of detecting giant planets and stellar companions orbiting individual stars in binary systems. We describe our observations for the survey, and introduce the wavelength calibration scheme that delivers precision at the tens of micro-arcseconds level for <0.2 arcsecond binaries. We test our instrument performance on a known triple system kappa Peg, and show that our survey is delivering a factor of 10 better precision than previous similar surveys. We…

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