The Astrophysical Journal Letters (Jan 2023)

Orbital Decay in an Accreting and Eclipsing 13.7 Minute Orbital Period Binary with a Luminous Donor

  • Kevin B. Burdge,
  • Kareem El-Badry,
  • Saul Rappaport,
  • Tin Long Sunny Wong,
  • Evan B. Bauer,
  • Lars Bildsten,
  • Ilaria Caiazzo,
  • Deepto Chakrabarty,
  • Emma Chickles,
  • Matthew J. Graham,
  • Erin Kara,
  • S. R. Kulkarni,
  • Thomas R. Marsh,
  • Melania Nynka,
  • Thomas A. Prince,
  • Robert A. Simcoe,
  • Jan van Roestel,
  • Zach Vanderbosch,
  • Eric C. Bellm,
  • Richard G. Dekany,
  • Andrew J. Drake,
  • George Helou,
  • Frank J. Masci,
  • Jennifer Milburn,
  • Reed Riddle,
  • Ben Rusholme,
  • Roger Smith

DOI
https://doi.org/10.3847/2041-8213/ace7cf
Journal volume & issue
Vol. 953, no. 1
p. L1

Abstract

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We report the discovery of ZTF J0127+5258, a compact mass-transferring binary with an orbital period of 13.7 minutes. The system contains a white dwarf accretor, which likely originated as a post–common envelope carbon–oxygen (CO) white dwarf, and a warm donor ( T _eff,donor = 16,400 ± 1000 K). The donor probably formed during a common envelope phase between the CO white dwarf and an evolving giant that left behind a helium star or white dwarf in a close orbit with the CO white dwarf. We measure gravitational wave–driven orbital inspiral with ∼51 σ significance, which yields a joint constraint on the component masses and mass transfer rate. While the accretion disk in the system is dominated by ionized helium emission, the donor exhibits a mixture of hydrogen and helium absorption lines. Phase-resolved spectroscopy yields a donor radial velocity semiamplitude of 771 ± 27 km s ^−1 , and high-speed photometry reveals that the system is eclipsing. We detect a Chandra X-ray counterpart with L _X ∼ 3 × 10 ^31 erg s ^−1 . Depending on the mass transfer rate, the system will likely either evolve into a stably mass-transferring helium cataclysmic variable, merge to become an R CrB star, or explode as a Type Ia supernova in the next million years. We predict that the Laser Space Interferometer Antenna (LISA) will detect the source with a signal-to-noise ratio of 24 ± 6 after 4 yr of observations. The system is the first LISA-loud mass-transferring binary with an intrinsically luminous donor, a class of sources that provide the opportunity to leverage the synergy between optical and infrared time domain surveys, X-ray facilities, and gravitational-wave observatories to probe general relativity, accretion physics, and binary evolution.

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