What question did this study set out to answer?

This research aims to understand the origins of spin-orbit misalignment in binary stars through their spin dynamics.

June 12, 2026

Spin-spin coupling in stellar binaries

Key Points

This research aims to understand the origins of spin-orbit misalignment in binary stars through their spin dynamics.
Studied secular spin dynamics of stellar binaries to derive Cassini states.
Isolated spin-spin resonance linked to combined stellar spin-precession frequencies.
Analyzed effects of magnetic braking and tidal dissipation on obliquity states.
Identified conditions where spin-spin resonance excites high obliquity states.
Found that magnetic braking leads to higher obliquities, while tidal dissipation reduces them.
Explained diversity of observed obliquities in young stellar binaries based on the dynamics studied.

Abstract

Spin--orbit misalignment is increasingly observed in binary stars, but its origin remains uncertain. We study the secular spin dynamics of stellar binaries and derive the associated Cassini states. We isolate a spin--spin resonance that arises when the two stellar spin-precession frequencies become commensurate. This resonance can excite the obliquity of the secondary to high values even when the primary is only weakly tilted. Magnetic braking favors the formation of high-obliquity states, whereas tidal dissipation may suppress them. Spin--spin coupling may thus help explain the observed diversity of obliquities in young stellar binaries.

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