Type a search term to find related articles by LIMS subject matter experts gathered from the most trusted and dynamic collaboration tools in the laboratory informatics industry.
Observation data Epoch J2000 Equinox J2000 | |
---|---|
Constellation | Taurus |
Right ascension | 04h 33m 52.01440s[1] |
Declination | +22° 50′ 30.0941″[1] |
Apparent magnitude (V) | 13.8[2] |
Characteristics | |
Evolutionary stage | T Tauri star |
Spectral type | K4IVe[2] |
Variable type | Orion variable |
Astrometry | |
Radial velocity (Rv) | +16.2[2] km/s |
Proper motion (μ) | RA: +8.942 mas/yr[1] Dec.: –17.079 mas/yr[1] |
Parallax (π) | 6.2376 ± 0.0205 mas[1] |
Distance | 523 ± 2 ly (160.3 ± 0.5 pc) |
Details | |
Mass | 0.90±0.02[3] M☉ |
Radius | 1.679[4] R☉ |
Rotation | 6.6 d[5] or 9 d[6] |
Age | 2-3[3] Myr |
Other designations | |
CI Tau, 2MASS J04335200+2250301, EPIC 247584113[2] | |
Database references | |
SIMBAD | data |
CI Tauri is a young star, about 2 million years old, located approximately 523 light-years (160 parsecs) away in the constellation Taurus. It is still accreting material from a debris disk at an unsteady pace, possibly modulated by the eccentric[8] orbital motion of an inner planet.[9] The spectral signatures of compounds of sulfur were detected from the disk.[10]
The magnetic field on the surface of CI Tauri, equal to 0.22 T, is close to average for T Tauri stars.[11]
CI Tauri hosts a protoplanetary disk, and evidence for planets has been found via both radial velocity and disk morphology.[12][6]
CI Tauri displays several periodic radial velocity variations, including periods of 6.6 days, 9 days, and 25 days.[6] The 9-day period was proposed to be due to a candidate massive planet on an eccentric orbit, CI Tauri b, in 2016.[13] The discovery of CI Tauri b was notable because it is a hot Jupiter, which are supposed to take a minimum of 10 million years to form, and are often thought to be too close to their parent stars to have formed there.[14][15]
The existence of this planet has been debated; in 2019, a detection of carbon monoxide attributed to the planet's atmosphere was announced, seemingly confirming it.[3] However, a 2020 study found that the star rotates with a period of 9 days, and suggested that the radial velocity variations may be caused by the star's rotation rather than a planet. The carbon monoxide detection was attributed to magnetic interaction of the star with the circumstellar disk.[16] Other studies have attributed the 6.6-day period to the stellar rotation and the 9-day period to the candidate planet.[9][5]
A 2024 study found evidence for a planetary origin of the 25-day radial velocity signal, while considering the 9-day signal to correspond to the stellar rotation and be caused by a starspot.[6] This 25-day candidate planet would orbit CI Tauri at a distance of 0.17 AU in a highly-eccentric orbit (e = 0.58). The mass of this planet is estimated to be 3.6±0.3 MJ.[6] While this is treated as a strong candidate and left undesignated by its discovery paper, the NASA Exoplanet Archive lists it as a confirmed planet with the designation CI Tauri c.[4]
In 2018 the possible detection of three more planets, inferred by gaps in the protoplanetary disk surrounding the star, was announced. Using the Atacama Large Millimeter Array (ALMA) to look for 'siblings' of CI Tauri b, a team of researchers detected three distinct gaps in the protoplanetary disk which their theoretical modelling suggests are caused by three other planets. The two outer planets are believed to be about the mass of Saturn, while the inner planet's mass is around the same as Jupiter.[15] Two of the new planets are similarly located to those inferred in the HL Tauri protoplanetary disk.[12]
Another 2018 study also found evidence for the outermost of these planets at around 100 AU, estimating a mass of 0.25-0.8 times that of Jupiter.[17] If this discovery is confirmed this would be the most massive collection of exoplanets ever detected at this age with its four planets spanning a factor of a thousand in orbital radius.[12]
The gaps are visible in wideband photography, but not in the gas spectral lines. These "gaps" may be lower-temperature shadows of dust in the inner disk cast on outer parts rather than true gaps carved by planets.[18]
Companion (in order from star) |
Mass | Semimajor axis (AU) |
Orbital period (days) |
Eccentricity | Inclination | Radius |
---|---|---|---|---|---|---|
b (false positive[4]) | 11.6+2.9 −2.7 MJ |
— | 8.9891±0.0202 | 0.25±0.16 | 50.5+6.3 −8.5° |
— |
c | 3.6±0.3 MJ | 0.17±0.08 | 25.2+1.7 −1.8 |
0.58+0.05 −0.06 |
— | — |
(unconfirmed) | ~0.75 MJ | ~14 | — | — | — | — |
(unconfirmed) | ~0.15 MJ | ~43 | — | — | — | — |
(unconfirmed) | ~0.4 MJ | ~108 | — | — | — | — |
debris disk[10] | 200–600 AU | 50.3° | — |