LP26175 (also known as TOI1779) is a triple star system in the constellation Leo Minor. It is composed of the primary red dwarf star, an eclipsing close companion brown dwarf and another brown dwarf in a wide orbit. The inner pair is one of the first red dwarfâÂÂbrown dwarf systems to have its obliquity measured by the RossiterâÂÂMcLaughlin effect, the other being TOI-2119. The system is thought to be a member of the AB Doradus Moving Group.
The brown dwarf LP26175B was discovered during the 2MASS survey on and announced in a 2000 discovery paper. Its association with the nearby primary star was first noted five years later after proper motion measurements confirmed that the two objects are co-moving, though confirmation with parallax was not yet available. The wide binary nature of the two objects was confirmed by 2006 by the spectroscopic method, confirming the common distance and young age of of the system.
Observations of the brown dwarf LP26175B obtained by the Hawaii Infrared Parallax Program at the CanadaâÂÂFranceâÂÂHawaii Telescope allowed for confirmation of common parallax with the primary. The obtained infrared spectrum was noted to show relatively strong FeH and alkali features, indicating higher gravity otherwise typical of old field brown dwarfs.
The inner transiting companion LP26175C was discovered by the MEarth transit survey based on observations in , followed up by confirmation by the spectroscopic method, which also revealed that the companion's mass is consistent with identification as a brown dwarf.
Observations performed at the Gemini North with the MAROON-X instrument during a transit on were used to characterize the RossiterâÂÂMcLaughlin effect for determination of the obliquity of the primary star with respect to the orbital plane of the inner transiting companion.
LP26175A is a young red dwarf star. Due to its mass of around it is thought to be fully convective.
The spectrum of LP26175A shows a strong Hñ emission feature, indicating strong chromospheric activity typical of young mid-M spectral type stars of ages around . It is also a suspected X-ray source, which can be explained by the expected coronal activity.
The star is rotating rapidly with a ~2.2day period, which is also a sign of the star's young age based on gyrochronology.
LP26175B is a wide orbit brown dwarf companion to the primary star, at a projected separation of . This separation is larger than the typical maximum separation for such low mass systems, but common for brown dwarf companions to higher mass stars. The young age offers an explanation for the survival of the weakly bound system.
While the mass of the brown dwarf cannot be directly measured without determination of the orbit, an estimation based on the evolutionary tracks is possible based on the assumed age of the primary in the range of . The effective temperature of matching the observed L6 spectral type corresponds to a low-mass brown dwarf in the range of .
Lightcurve measurements of LP26175B revealed a most likely rotation period of with variability of at least across the entire observed infrared wavelength range with a minimal slope and no measurable decrease in the water absorption band, which would be expected to be visible at pressures above . This implies that the variations in the lightcurve are likely caused by presence of heterogeneous clouds or hazes present above that altitude. In addition, a strong secondary period of , close to one third of the main period, was also found in the periodogram, which could be caused by a persistent symmetric pattern of cloud features on each hemisphere.
The orbital period of LP26175C is ~1.88days, which is shorter than the primary's rotational period. Tidal interactions are expected to lead to tidal locking meaning spinâÂÂorbit synchronization, however as the system is still young, it is likely that the final state has not been reached yet. The current orbit places it within the brown dwarf desert.
The obliquity of the orbit of the brown dwarf with respect to the axis of rotation of the star has been measured by characterizing the RossiterâÂÂMcLaughlin effect. The measured value of projected obliquity is û = , which, combined with inclinations of the orbit and the star's axis of rotation results in true obliquity of à= , meaning the system is aligned. As the system is younger than the timescale thought to be necessary for tidal interactions to align the orbit, this alignment is likely primordial.
The mass and radius of LP26175C are well-known from the radial velocity and transit photometry measurements. The obtained values of and can be compared to the theoretical isochrones, which predict how brown dwarfs cool, contract and dim through their lifetimes. The radius is smaller than expected for a brown dwarf with an age of approximately , corresponding more closely to the value expected for for a given mass. As the young age of the system is otherwise well-established, this implies a gap in the current evolutionary models for the brown dwarfs.