# New constraints on the dust and gas distribution in the LkCa 15 disk   from ALMA

**Authors:** Sheng Jin, Andrea Isella, Pinghui Huang, Shengtai Li, Hui Li, Jianghui, Ji

arXiv: 1907.00571 · 2019-09-04

## TL;DR

This study models the LkCa 15 disk using ALMA data to constrain its gas and dust distribution, revealing a large cavity, a steep density profile, and a discrepancy between gas and dust disk sizes.

## Contribution

It provides the first detailed modeling of the LkCa 15 disk’s gas density profile and compares it with dust observations, highlighting dust trapping and drift effects.

## Key findings

- Disk mass estimated at ~0.1 solar masses
- Inner cavity radius of 45 AU in gas disk
- Outer edge of gas disk at ~600 AU, dust at ~200 AU

## Abstract

We search a large parameter space of the LkCa 15's disk density profile to fit its observed radial intensity profile of $^{12}$CO (J = 3-2) obtained from ALMA. The best-fit model within the parameter space has a disk mass of 0.1 $M_{\odot}$ (using an abundance ratio of $^{12}$CO/H$_2$ $=$ 1.4 $\times 10^{-4}$ in mass), an inner cavity of 45 AU in radius, an outer edge at $\sim$ 600 AU, and a disk surface density profile follows a power-law of the form $\rho_r \propto r^{-4}$. For the disk density profiles that can lead to a small reduced $\chi^2$ of goodness-of-fit, we find that there is a clear linear correlation between the disk mass and the power-law index $\gamma$ in the equation of disk density profile. This suggests that the $^{12}$CO disk of LkCa 15 is optically thick and we can fit its $^{12}$CO radial intensity profile using either a lower disk mass with a smaller $\gamma$ or a higher disk mass with a bigger $\gamma$. By comparing the $^{12}$CO channel maps of the best-fit model with disk models with higher or lower masses, we find that a disk mass of $\sim$ 0.1 $M_{\odot}$ can best reproduce the observed morphology of the $^{12}$CO channel maps. The dust continuum map at 0.87 mm of the LkCa 15 disk shows an inner cavity of the similar size of the best-fit gas model, but its out edge is at $\sim$ 200 AU, much smaller than the fitted gas disk. Such a discrepancy between the outer edges of the gas and dust disks is consistent with dust drifting and trapping models.

## Full text

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## Figures

9 figures with captions in the complete paper: https://tomesphere.com/paper/1907.00571/full.md

## References

66 references — full list in the complete paper: https://tomesphere.com/paper/1907.00571/full.md

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Source: https://tomesphere.com/paper/1907.00571