MINDS: Detection of an inner gas disk caused by evaporating bodies around HD 172555

M. Samland; T. Henning; A. Caratti o Garatti; T. Giannini; J. Bouwman; B. Tabone; A. M. Arabhavi; G. Olofsson; M. G\"udel; N. Pawellek; I. Kamp; L. B. F. M. Waters; D. Semenov; E. F. van Dishoeck; O. Absil; D. Barrado; A. Boccaletti; V. Christiaens; D. Gasman; S. L. Grant; H. Jang; T. Kaeufer; J. Kanwar; G. Perotti; K. Schwarz; M. Temmink

arXiv:2506.09976·astro-ph.EP·July 21, 2025

MINDS: Detection of an inner gas disk caused by evaporating bodies around HD 172555

M. Samland, T. Henning, A. Caratti o Garatti, T. Giannini, J. Bouwman, B. Tabone, A. M. Arabhavi, G. Olofsson, M. G\"udel, N. Pawellek, I. Kamp, L. B. F. M. Waters, D. Semenov, E. F. van Dishoeck, O. Absil, D. Barrado, A. Boccaletti, V. Christiaens, D. Gasman, S. L. Grant

PDF

Open Access

TL;DR

This study uses JWST observations to detect and analyze an inner gaseous disk around HD 172555, revealing evaporating rocky bodies and their composition, providing insights into planetary building blocks beyond the Solar System.

Contribution

First detection of an inner gas disk caused by evaporating bodies in a debris disk, with detailed compositional analysis using JWST data.

Findings

01

Detection of neutral atomic chlorine and sulfur, and ionized nickel in the inner disk.

02

Gas is hotter, closer to the star, and poor in argon compared to beta Pic.

03

Gas lines are broadened by Keplerian rotation, pinpointing their location.

Abstract

Mechanisms such as collisions of rocky bodies or cometary activity give rise to dusty debris disks. Debris disks trace the leftover building blocks of planets, and thus also planetary composition. HD 172555, a stellar twin of beta Pic, hosts a debris disk thought to have resulted from a giant collision. It is known for its extreme mid-infrared silica dust feature, indicating a warm population of silica-rich grains in the asteroid belt (~5 au), cold CO observed by ALMA, and small bodies evaporating as they approach close to the star. Our JWST MIRI/MRS observations now reveal emission from an inner gaseous disk (<0.5 au) that arises from the evaporation of close-in material. For the first time in a debris disk, we detect neutral atomic chlorine and sulfur, as well as ionized nickel. We recovered the neutral sulfur line in ~20-year-old Spitzer data, showing it is long-lived and stable.…

Peer Reviews

No public reviews on file for this paper yet. If you reviewed it on a platform where reviews are public (OpenReview, ICLR, NeurIPS, ICML), you can paste yours below so the community can read it here.

Videos

No videos yet. Explain this paper in a talk, walkthrough, or lecture? Add one.

Taxonomy

TopicsAstro and Planetary Science · Stellar, planetary, and galactic studies · Astrophysics and Star Formation Studies