Saved in:
Bibliographic Details
Main Authors: Viscardi, Elena M., Macías, Enrique, Zagaria, Francesco, Sierra, Anibal, Jiang, Haochang, Yoshida, Tomohiro, Curone, Pietro
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.13877
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866909464631705600
author Viscardi, Elena M.
Macías, Enrique
Zagaria, Francesco
Sierra, Anibal
Jiang, Haochang
Yoshida, Tomohiro
Curone, Pietro
author_facet Viscardi, Elena M.
Macías, Enrique
Zagaria, Francesco
Sierra, Anibal
Jiang, Haochang
Yoshida, Tomohiro
Curone, Pietro
contents Multi-wavelength dust continuum observations of protoplanetary disks are essential for accurately measuring two key ingredients of planets formation theories: the dust mass and grain size. Unfortunately, they are also extremely time-expensive. We aim to investigate the most economic way of performing this analysis. We benchmark the dust characterization analysis on multi-wavelength observations of two disk models. We test three different combinations of bands (in the 0.45 mm $\to$ 7.46 mm range) to see how optically thick and thin observations aid the reconstruction of the dust properties for different morphologies and in three different dust mass regimes. We also test different spatial resolutions. Dust properties are robustly measured in a multi-band analysis if optically thin observations are included. For typical disks, this requires wavelengths longer than 3 mm. High-resolution (< 0.03"-0.05") is fundamental to resolve the changes in dust content of substructures. However, lower-resolution results still provide an accurate measurement of the total dust mass and of the level of grain growth of rings. Additionally, we propose a new approach that successfully combines lower and higher resolution observations in the multi-wavelength analysis without losing spatial information. We also test individually enhancing the resolution of each radial intensity profile with Frank but we note the presence of artifacts. Finally, we discuss on the total dust mass that we derive from the SED analyses and compare it with the traditional method of deriving dust masses from millimeter fluxes. Accurate dust mass measurements from the SED analysis can be derived by including optically thin tracers. On the other hand, single-wavelength flux-based masses are always underestimated by even more than one order of magnitude.
format Preprint
id arxiv_https___arxiv_org_abs_2501_13877
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Dust characterization of protoplanetary disks: a guide to multi-wavelength analyses and accurate dust mass measurements
Viscardi, Elena M.
Macías, Enrique
Zagaria, Francesco
Sierra, Anibal
Jiang, Haochang
Yoshida, Tomohiro
Curone, Pietro
Earth and Planetary Astrophysics
Solar and Stellar Astrophysics
Multi-wavelength dust continuum observations of protoplanetary disks are essential for accurately measuring two key ingredients of planets formation theories: the dust mass and grain size. Unfortunately, they are also extremely time-expensive. We aim to investigate the most economic way of performing this analysis. We benchmark the dust characterization analysis on multi-wavelength observations of two disk models. We test three different combinations of bands (in the 0.45 mm $\to$ 7.46 mm range) to see how optically thick and thin observations aid the reconstruction of the dust properties for different morphologies and in three different dust mass regimes. We also test different spatial resolutions. Dust properties are robustly measured in a multi-band analysis if optically thin observations are included. For typical disks, this requires wavelengths longer than 3 mm. High-resolution (< 0.03"-0.05") is fundamental to resolve the changes in dust content of substructures. However, lower-resolution results still provide an accurate measurement of the total dust mass and of the level of grain growth of rings. Additionally, we propose a new approach that successfully combines lower and higher resolution observations in the multi-wavelength analysis without losing spatial information. We also test individually enhancing the resolution of each radial intensity profile with Frank but we note the presence of artifacts. Finally, we discuss on the total dust mass that we derive from the SED analyses and compare it with the traditional method of deriving dust masses from millimeter fluxes. Accurate dust mass measurements from the SED analysis can be derived by including optically thin tracers. On the other hand, single-wavelength flux-based masses are always underestimated by even more than one order of magnitude.
title Dust characterization of protoplanetary disks: a guide to multi-wavelength analyses and accurate dust mass measurements
topic Earth and Planetary Astrophysics
Solar and Stellar Astrophysics
url https://arxiv.org/abs/2501.13877