A gas density drop in the inner 6 AU of the transition disk around the Herbig Ae star HD 139614 . Further evidence for a giant planet inside the disk?

Author(s)

A. Carmona, W.-F. Thi, I. Kamp, Manuel Güdel

Abstract

Context. Quantifying the gas surface density inside the dust cavities and gaps of transition disks is important to establish their origin. Aims. We seek to constrain the surface density of warm gas in the inner disk of HD 139614, an accreting 9 Myr Herbig Ae star with a (pre-)transition disk exhibiting a dust gap from 2.3 ± 0.1 to 5.3 ± 0.3 AU. Methods. We observed HD 139614 with ESO/VLT CRIRES and obtained high-resolution (R ∼ 90 000) spectra of CO ro-vibrational emission at 4.7 μm.We derived constraints on the disk's structure by modeling the CO isotopolog line-profiles, the spectroastrometric signal, and the rotational diagrams using grids of flat Keplerian disk models. Results. We detected ν = 1 → 0

¹²CO, 2 → 1

¹²CO, 1→ 0

¹³CO, 1→ 0 C

¹⁸O, and 1→ 0 C

¹⁷O ro-vibrational lines. Lines are consistent with disk emission and thermal excitation.

¹²CO ν = 1 → 0 lines have an average width of 14 km s

^-1, T

_gas of 450 K and an emitting region from 1 to 15 AU.

¹³CO and C

¹⁸O lines are on average 70 and 100 K colder, 1 and 4 km s

^-1 narrower than

¹²CO ν = 1 → 0, and are dominated by emission at R ≥ 6 AU. The

¹²CO ν = 1 → 0 composite line-profile indicates that if there is a gap devoid of gas it must have a width narrower than 2 AU. We find that a drop in the gas surface density (δ

_gas) at R < 5-6 AU is required to be able to simultaneously reproduce the line-profiles and rotational diagrams of the three CO isotopologs. Models without a gas density drop generate

¹³CO and C

¹⁸O emission lines that are too broad and warm. The value of δ

_gas can range from 10

^-2 to 10

^-4 depending on the gas-to-dust ratio of the outer disk. We find that the gas surface density profile at 1 < R < 6 AU is flat or increases with radius. We derive a gas column density at 1 < R < 6 AU of N

_H = 3 × 10

¹⁹ -10

²¹ cm

^-2 (7 × 10

^-5-2:4 × 10

^-3 g cm

^-2) assuming N

_CO = 10

^-4N

_H. We find a 5σ upper limit on the CO column density N

_CO at R ≤ 1 AU of 5 × 10

¹⁵ cm

^-2 (N

_H ≤ 5 × 10

¹⁹ cm

^-2). Conclusions. The dust gap in the disk of HD 139614 has molecular gas. The distribution and amount of gas at R ≤ 6 AU in HD 139614 is very different from that of a primordial disk. The gas surface density in the disk at R ≤ 1 AU and at 1 < R < 6 AU is significantly lower than the surface density that would be expected from the accretion rate of HD 139614 (10

^-8 M

_⊙ yr

^-1) assuming a standard viscous α-disk model. The gas density drop, the non-negative density gradient in the gas inside 6 AU, and the absence of a wide (>2 AU) gas gap, suggest the presence of an embedded <2 M

_J planet at around 4 AU.

Organisation(s)

Department of Astrophysics

External organisation(s)

Max-Planck-Institut für extraterrestrische Physik, University of Groningen, Université de Genève

Journal

Astronomy & Astrophysics

Volume

598

No. of pages

29

ISSN

0004-6361

DOI

https://doi.org/10.1051/0004-6361/201628472

Publication date

02-2017

Peer reviewed

Yes

Austrian Fields of Science 2012

103003 Astronomy, 103004 Astrophysics

Keywords

ASJC Scopus subject areas

Astronomy and Astrophysics, Space and Planetary Science

Portal url

https://ucrisportal.univie.ac.at/en/publications/3cea3cd1-9285-44bc-aad4-e9bfaf29675f