The Astrophysical Journal Letters (Jan 2024)

The Unluckiest Star: A Spectroscopically Confirmed Repeated Partial Tidal Disruption Event AT 2022dbl

  • Zheyu Lin,
  • Ning Jiang,
  • Tinggui Wang,
  • Xu Kong,
  • Dongyue Li,
  • Han He,
  • Yibo Wang,
  • Jiazheng Zhu,
  • Wentao Li,
  • Ji-an Jiang,
  • Avinash Singh,
  • Rishabh Singh Teja,
  • D. K. Sahu,
  • Chichuan Jin,
  • Keiichi Maeda,
  • Shifeng Huang

DOI
https://doi.org/10.3847/2041-8213/ad638e
Journal volume & issue
Vol. 971, no. 1
p. L26

Abstract

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The unluckiest star orbits a supermassive black hole elliptically. Every time it reaches the pericenter, it shallowly enters the tidal radius and gets partially tidally disrupted, producing a series of flares. Confirmation of a repeated partial tidal disruption event (pTDE) requires not only evidence to rule out other types of transients but also proof that only one star is involved, as TDEs from multiple stars can also produce similar flares. In this Letter, we report the discovery of a repeated pTDE, AT 2022dbl. In a quiescent galaxy at z = 0.0284, two separate optical/UV flares have been observed in 2022 and 2024 with no bright X-ray, radio, or mid-infrared counterparts. Compared to the first flare, the second flare has a similar blackbody temperature of ∼26,000 K, slightly lower peak luminosity, and slower rise and fall phases. Compared to the Zwicky Transient Facility TDEs, their blackbody parameters and light-curve shapes are all similar. The spectra taken during the second flare show a steeper continuum than the late-time spectra of the previous flare, consistent with a newly risen flare. More importantly, the possibility of two independent TDEs can be largely ruled out because the optical spectra taken around the peak of the two flares exhibit highly similar broad Balmer, N iii, and possible He ii emission lines, especially the extreme ∼4100 Å emission lines. This represents the first robust spectroscopic evidence for a repeated pTDE, which can soon be verified by observing the third flare, given its short orbital period.

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