Tidal Interactions between Binary Stars Can Drive Lithium Production in Low-mass Red Giants

Andrew R. Casey, Anna Y. Q. Ho, Melissa Ness, David W. Hogg, Hans-Walter Rix, George C. Angelou, Saskia Hekker, Christopher A. Tout, John C. Lattanzio, Amanda I. Karakas, Tyrone E. Woods, Adrian M. Price-Whelan, Kevin C. Schlaufman

    Research output: Contribution to journalArticlepeer-review

    69 Citations (Scopus)

    Abstract

    Theoretical models of stellar evolution predict that most of the lithium inside a star is destroyed as the star becomes a red giant. However, observations reveal that about 1% of red giants are peculiarly rich in lithium, often exceeding the amount in the interstellar medium or predicted from the big bang. With only about 150 lithium-rich giants discovered in the past four decades, and no distinguishing properties other than lithium enhancement, the origin of lithium-rich giant stars is one of the oldest problems in stellar astrophysics. Here we report the discovery of 2330 low-mass (1-3 M ) lithium-rich giant stars, which we argue are consistent with internal lithium production that is driven by tidal spin-up by a binary companion. Our sample reveals that most lithium-rich giants have helium-burning cores ({80}-6+7 % ), and that the frequency of lithium-rich giants rises with increasing stellar metallicity. We find that while planet accretion may explain some lithium-rich giants, it cannot account for the majority that have helium-burning cores. We rule out most other proposed explanations for the origin of lithium-rich giants. Our analysis shows that giants remain lithium-rich for only about two million years. A prediction from this lithium depletion timescale is that most lithium-rich giants with a helium-burning core have a binary companion.
    Original languageEnglish
    JournalAstrophysical Journal
    Volume880
    DOIs
    Publication statusPublished - 1 Aug 2019

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