Hot exozodiacal dust around Fomalhaut: The MATISSE perspective

TL;DR

This study used the MATISSE instrument at VLTI to detect and characterize hot exozodiacal dust around Fomalhaut, providing new constraints on dust parameters and highlighting the importance of geometric modeling.

Contribution

First interferometric observations of Fomalhaut's HEZD with MATISSE in L and M bands, offering new constraints and demonstrating the impact of geometric models on parameter estimation.

Findings

Marginal detection of circumstellar radiation in L band.

Dust ring with inner radius 0.11 au and outer radius 0.12 au.

Dust mass estimated at 3.25×10^{-10} M_⊕.

Abstract

Excess over the stellar photospheric emission of main-sequence stars has been found in interferometric near-infrared observations, and is attributed to the presence of hot exozodiacal dust (HEZD). As part of our effort to detect and characterize HEZD around the nearby A3 V star Fomalhaut, we carried out the first interferometric observations with the MATISSE instrument at the VLTI in the photometric bands L and M for the Fomalhaut system. Assuming a dust distribution either as a narrow ring or spherical shell for modeling the HEZD, we aim to constrain the HEZD parameters by generating visibilities and fitting them to the MATISSE data using different approaches. The L band data provide a marginal detection of circumstellar radiation, potentially caused by the presence of HEZD, which is only the second detection of HEZD emission in the L band. An analysis of the data with different fitting approaches showed that the best-fit values for the HEZD parameters are consistent with those of previous Fomalhaut observations, which underlines the functionality of MATISSE. Assuming a dust ring, it would have an inner ring radius of \(0.11\ \mathrm{au}\), an outer ring radius of \(0.12\ \mathrm{au}\), a narrow dust grain size distribution around a dust grain radius constrained by \(0.53\ \mu\mathrm{m}\), and a total dust mass of \(3.25\times 10^{-10}\ \rm{M}_{\oplus}\). Finally, the results indicate that the choice of the geometric model has a more significant impact on the derived dust-to-star flux ratio than the specific fitting approach applied. Since different dust-to-star flux ratios can result from the applied fitting approaches, this also has an impact on the parameter values of the HEZD around Fomalhaut and most likely for other HEZD systems. Moreover, further NIR and MIR data are required for a more comprehensive description of the emission originating in the vicinity of Fomalhaut.