JWST/NIRCam observations of HD~92945 debris disk: An asymmetric disk with a gap

TL;DR

This study uses JWST/NIRCam to observe the HD 92945 debris disk, revealing a broad, inclined disk with a gap and brightness asymmetries, supporting the presence of unseen planetary companions shaping the system.

Contribution

First JWST/NIRCam high-contrast imaging of HD 92945 debris disk, confirming a gap and asymmetries, and constraining potential planetary companions.

Findings

Disk shows a gap at ~80 au.

Brightness asymmetry observed in the inner ring.

No planetary companions more massive than ~0.5 MJ beyond 100 au detected.

Abstract

We present the first observations of the HD92945 debris disk obtained with JWST, targeting this nearby K0V star located at 21.54 pc from the Sun. High-contrast coronagraphic imaging was performed using JWST/NIRCam in the F200W and F444W filters. After subtracting the disk contribution through forward modeling by means of synthetic PSFs and MCMC optimizations, the residuals were analyzed to identify candidate point sources. From these, we derived contrast curves and constructed detection probability maps for substellar companions. The disk is clearly detected in both NIRCam filters and reveals a broad, inclined structure with a gap, consistent with previous scattered-light and ALMA observations. The modeling confirms the presence of a gap at ~80 au and shows a scale height and scattering properties compatible with a dynamically active disk. A significant brightness asymmetry is observed in the southwestern inner ring at both 2 and 4.4 {\mu}m, consistent with previous ALMA results. Observing this feature across different wavelengths and epochs strongly supports a scenario where one or more unseen planetary companions are perturbing the disk. No comoving sources are detected, and all candidate objects in the field are consistent with background stars or galaxies. The derived detection limits exclude planets more massive than ~0.4-0.5 MJ beyond 100 au and more massive than ~1 MJ beyond 20-40 au. This, in turn, rules out the possibility of a single planet placed beyond ~20 au as responsible for the astrometric signal observed by Gaia. These results, combined with the observed disk features, support a scenario in which a single or multiple sub-Jupiter planets dynamically shape the system through mechanisms such as secular apsidal resonances, providing a coherent explanation for the gap, the asymmetric brightness distribution and the astrometric signal.