HD 139139


HD 139139 is likely part of a bound pair system of main sequence stars about away from Earth in the constellation Libra. HD 139139 is a G-type main-sequence star, a little larger and more luminous than the Sun, and at an almost identical temperature. It has an apparent magnitude of 9.8. The companion star is thought to be a K5-K7 red dwarf away from HD 139139. It is about three magnitudes fainter and has a temperature of between 4,100 and. Both stars have a similar proper motion, meaning they may form a gravitationally-bound binary pair.
HD 139139 exhibits dips in brightness similar to those caused by transiting Earth-like planets. The Kepler [space telescope] observed 28 dips in their brightness over an 87-day period. The dips do not appear to be periodic as would be expected if they were due to transiting planets.
It is unknown which of the two stars produces the dimming events. Potential explanations that have been investigated include planets transiting a binary star, planets that are perturbing the orbits of each other producing large transit timing variations, a disintegrating planet, large dust producing asteroids, and short lived sunspots. According to Andrew Vanderburg, one of the researchers of the original studies,
Subsequent observations performed with CHEOPS in two observing campaigns in the years 2021 and 2022 detected no transit-like events. The team estimated 4.8% probability of having missed all of them by chance, assuming that the frequency of the events remained unchanged from the 2017 measurements by Kepler. While it is possible that the events detected by Kepler were real, but inactive during observations by CHEOPS, the team also noted that it is not possible to discard also the possibility that they were caused by unidentified and infrequent instrumentation error.

Background

HD 139139 was identified as unusual by two independent groups of visual surveyors working in collaboration with professional astronomers.
HD 139139 is one of the 0.5% of stars in the sky that can see Earth transit, according to Andrew Vanderburg. "The transit impact parameter would be close to 0.9, so they can just barely see us – the transit duration would be only about 40% the duration we'd expect for a perfectly edge-on transit."