# Using Ice and Dust Lines to Constrain the Surface Densities of   Protoplanetary Disks

**Authors:** Diana Powell, Ruth Murray-Clay, and Hilke E. Schlichting

arXiv: 1704.04693 · 2019-08-19

## TL;DR

This paper introduces a new method using dust and ice lines to measure the surface density of protoplanetary disks, validated on TW Hya and supported by theoretical modeling.

## Contribution

The novel approach links dust and ice lines to surface density, providing a new way to estimate disk properties and test disk evolution models.

## Key findings

- Surface density profiles are consistent with HD gas measurements.
- Theoretical CO ice line estimates match observational data.
- Predicted diagnostic tests for disk surface density profiles.

## Abstract

We present a novel method for determining the surface density of protoplanetary disks through consideration of disk 'dust lines' which indicate the observed disk radial scale at different observational wavelengths. This method relies on the assumption that the processes of particle growth and drift control the radial scale of the disk at late stages of disk evolution such that the lifetime of the disk is equal to both the drift timescale and growth timescale of the maximum particle size at a given dust line. We provide an initial proof of concept of our model through an application to the disk TW Hya and are able to estimate the disk dust-to-gas ratio, CO abundance, and accretion rate in addition to the total disk surface density. We find that our derived surface density profile and dust-to-gas ratio are consistent with the lower limits found through measurements of HD gas. The CO ice line also depends on surface density through grain adsorption rates and drift and we find that our theoretical CO ice line estimates have clear observational analogues. We further apply our model to a large parameter space of theoretical disks and find three observational diagnostics that may be used to test its validity. First we predict that the dust lines of disks other than TW Hya will be consistent with the normalized CO surface density profile shape for those disks. Second, surface density profiles that we derive from disk ice lines should match those derived from disk dust lines. Finally, we predict that disk dust and ice lines will scale oppositely, as a function of surface density, across a large sample of disks.

## Full text

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## Figures

16 figures with captions in the complete paper: https://tomesphere.com/paper/1704.04693/full.md

## References

85 references — full list in the complete paper: https://tomesphere.com/paper/1704.04693/full.md

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Source: https://tomesphere.com/paper/1704.04693