Eppur si eclissa: Eccentric low-mass companions and time-in-dust selection explain long secondary periods

TL;DR

This paper proposes that long secondary periods in pulsating red giants can be explained by eccentric, low-mass companions partially within dust formation zones, matching multiple observational constraints through analytical and hydrodynamical modeling.

Contribution

It introduces a novel model involving eccentric low-mass companions that spend part of their orbit within dust zones, explaining key observational features of LSPs.

Findings

The model reproduces the observed argument of periastron greater than 180 degrees.

Predicted LSP detectability is about 27% for SRVs and 2.5% for Miras.

Hydrodynamical simulations match observed phase offsets in radial velocity and light curves.

Abstract

[abbreviated] Long Secondary Periods (LSPs) are observed in about one third of pulsating red giants yet remain unexplained. Four key observational constraints anchor the discussion: (i) a roughly 30 percent occurrence rate in semi-regular variable AGB stars (SRVs), with a much lower rate or absence in regularly pulsating Mira-type AGB stars (Miras), (ii) about 50 percent of LSP stars show a secondary mid-infrared minimum, (iii) Keplerian fits to radial-velocity curves favor argument of periastron greater than 180 degrees, and (iv) the radial-velocity to light-curve phase lag clusters around minus 90 degrees. We test whether a close-in, eccentric, low-mass companion that spends only part of its orbit within the giant's dust-formation zone can match all four empirical constraints. Guided by observed radial-velocity amplitudes and periods of about 500 to 1500 days, we adopt companion masses of 0.08 to 0.25 solar masses, orbital separations of 1.5 to 3 AU, eccentricities up to 0.6, and dust condensation radii of about 2.5 to 3 AU for SRVs (larger for Miras via scaling with luminosity). We compute the fraction of the orbit spent outside the condensation radius and apply line-of-sight criteria for detectability. We test the first three empirical constraints analytically, then model the phase offset using three-dimensional hydrodynamical simulations. Our scenario explains the observed excess of systems with argument of periastron greater than 180 degrees and yields LSP detectability of about 27 percent for SRVs and about 2.5 percent for Miras, with a conditional secondary mid-infrared eclipse fraction of about 44 percent. The hydrodynamical models place the optical-depth maximum downstream of the companion near apastron and then shift it forward by roughly 90 to 225 degrees later in the orbit, consistent with the observed radial-velocity to light-curve offsets.