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Main Authors: Sethi, Ritika, Martin, David V., Barker, Adrian, Maxted, Pierre F. L., Triaud, Amaury H. M. J., Kunovac, Vedad, Tubthong, Wata, Duck, Alison, Bouchy, François, Udry, Stéphane
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.04554
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author Sethi, Ritika
Martin, David V.
Barker, Adrian
Maxted, Pierre F. L.
Triaud, Amaury H. M. J.
Kunovac, Vedad
Tubthong, Wata
Duck, Alison
Bouchy, François
Udry, Stéphane
author_facet Sethi, Ritika
Martin, David V.
Barker, Adrian
Maxted, Pierre F. L.
Triaud, Amaury H. M. J.
Kunovac, Vedad
Tubthong, Wata
Duck, Alison
Bouchy, François
Udry, Stéphane
contents Tidal interactions in close stellar binaries are central to their orbital and rotational evolution, making observational tests of theoretical predictions essential for our understanding of the evolution of these, as well as close exoplanetary systems. Such tests require precise measurements of the orbital eccentricity and stellar rotation. The EBLM (Eclipsing Binary Low Mass) survey delivers a homogeneous sample of eclipsing binaries, composed of F/G/K primaries and M-dwarf (or low-mass K-dwarf) secondaries. We analyze 68 unequal mass binaries ($0.1 \leq q \leq 0.6$, where $q$ is the mass ratio), with measurable primary star rotation rates from TESS, and over a decade of radial velocity observations. This sample probes the critical regime where tidal effects are expected to transition between being efficient and inefficient. We find that ~75% of our sample has circularized, with eccentric systems confined to $P_{\rm orb} \gtrsim 3$ days, with modest eccentricities (e < 0.25). Roughly ~78% of our sample is synchronized, with nearly all binaries within a 3-day orbital period residing in a well-defined "synchronization zone". Beyond this, a minority of asynchronous systems persist, which cannot be easily explained by our application of current tidal mechanisms or by differential rotation.
format Preprint
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institution arXiv
publishDate 2026
record_format arxiv
spellingShingle EBLM XVII - Tidal Synchronization and Circularization in Tight Stellar Binaries
Sethi, Ritika
Martin, David V.
Barker, Adrian
Maxted, Pierre F. L.
Triaud, Amaury H. M. J.
Kunovac, Vedad
Tubthong, Wata
Duck, Alison
Bouchy, François
Udry, Stéphane
Solar and Stellar Astrophysics
Tidal interactions in close stellar binaries are central to their orbital and rotational evolution, making observational tests of theoretical predictions essential for our understanding of the evolution of these, as well as close exoplanetary systems. Such tests require precise measurements of the orbital eccentricity and stellar rotation. The EBLM (Eclipsing Binary Low Mass) survey delivers a homogeneous sample of eclipsing binaries, composed of F/G/K primaries and M-dwarf (or low-mass K-dwarf) secondaries. We analyze 68 unequal mass binaries ($0.1 \leq q \leq 0.6$, where $q$ is the mass ratio), with measurable primary star rotation rates from TESS, and over a decade of radial velocity observations. This sample probes the critical regime where tidal effects are expected to transition between being efficient and inefficient. We find that ~75% of our sample has circularized, with eccentric systems confined to $P_{\rm orb} \gtrsim 3$ days, with modest eccentricities (e < 0.25). Roughly ~78% of our sample is synchronized, with nearly all binaries within a 3-day orbital period residing in a well-defined "synchronization zone". Beyond this, a minority of asynchronous systems persist, which cannot be easily explained by our application of current tidal mechanisms or by differential rotation.
title EBLM XVII - Tidal Synchronization and Circularization in Tight Stellar Binaries
topic Solar and Stellar Astrophysics
url https://arxiv.org/abs/2603.04554