# The Disk Gas Mass and the Far-IR Revolution

**Authors:** Edwin A. Bergin, Klaus M. Pontoppidan, Charles M. Bradford, L., Ilsedore Cleeves, Neal J. Evans, Maryvonne Gerin, Paul F. Goldsmith, Quentin, Kral, Gary J. Melnick, Melissa McClure, Karin Oberg, Thomas L. Roellig,, Edward Wright, Richard Teague, Jonathan P. Williams, Ke Zhang

arXiv: 1903.08777 · 2019-03-22

## TL;DR

The paper discusses how far-infrared observations, especially of hydrogen deuteride (HD), can revolutionize measurements of protoplanetary disk gas mass, crucial for understanding planet formation and disk evolution.

## Contribution

It highlights the potential of a space-based far-infrared telescope to survey disk gas masses via HD emission, enabling statistical studies across different stages and types of star systems.

## Key findings

- Far-infrared observations can significantly improve disk gas mass measurements.
- HD emission provides a more accurate tracer than traditional methods.
- A space-based 8 K telescope could survey hundreds of disks.

## Abstract

The gaseous mass of protoplanetary disks is a fundamental quantity in planet formation. The presence of gas is necessary to assemble planetesimals, it determines timescales of giant planet birth, and it is an unknown factor for a wide range of properties of planet formation, from chemical abundances (X/H) to the mass efficiency of planet formation. The gas mass obtained from traditional tracers, such as dust thermal continuum and CO isotopologues, are now known to have significant (1 - 2 orders of magnitude) discrepancies. Emission from the isotopologue of H2, hydrogen deuteride (HD), offers an alternative measurement of the disk gas mass.   Of all of the regions of the spectrum, the far-infrared stands out in that orders of magnitude gains in sensitivity can be gleaned by cooling a large aperture telescope to 8 K. Such a facility can open up a vast new area of the spectrum to exploration. One of the primary benefits of this far-infrared revolution would be the ability to survey hundreds of planet-forming disks in HD emission to derive their gaseous masses. For the first time, we will have statistics on the gas mass as a function of evolution, tracing birth to dispersal as a function of stellar spectral type. These measurements have broad implications for our understanding of the time scale during which gas is available to form giant planets, the dynamical evolution of the seeds of terrestrial worlds, and the resulting chemical composition of pre-planetary embryos carrying the elements needed for life. Measurements of the ground-state line of HD requires a space-based observatory operating in the far-infrared at 112 microns.

## Full text

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## Figures

3 figures with captions in the complete paper: https://tomesphere.com/paper/1903.08777/full.md

## References

19 references — full list in the complete paper: https://tomesphere.com/paper/1903.08777/full.md

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Source: https://tomesphere.com/paper/1903.08777