# Save the Planet, Feed the Star: How Super-Earths Survive Migration and   Drive Disk Accretion

**Authors:** Jeffrey Fung, Eugene Chiang

arXiv: 1701.08161 · 2017-04-26

## TL;DR

This paper investigates how super-Earths in inviscid disks can survive migration and contribute to disk dispersal by using 2D hydrodynamics simulations, revealing slow migration and efficient gas clearing mechanisms.

## Contribution

It demonstrates that in inviscid, laminar disks, super-Earths can slow migration and torque gas out of the system, providing a new perspective on planet survival and disk dispersal processes.

## Key findings

- Super-Earths can significantly slow or halt migration in inviscid disks.
- Gas is torqued inward and outward, aiding disk dispersal.
- Transport rates scale with disk surface density and planet mass.

## Abstract

Two longstanding problems in planet formation include (1) understanding how planets survive migration, and (2) articulating the process by which protoplanetary disks disperse---and in particular how they accrete onto their central stars. We can go a long way toward solving both problems if the disk gas surrounding planets has no intrinsic diffusivity ("viscosity"). In inviscid, laminar disks, a planet readily repels gas away from its orbit. On short timescales, zero viscosity gas accumulates inside a planet's orbit to slow Type I migration by orders of magnitude. On longer timescales, multiple super-Earths (distributed between, say, $\sim$0.1--10 AU) can torque inviscid gas out of interplanetary space, either inward to feed their stars, or outward to be blown away in a wind. We explore this picture with 2D hydrodynamics simulations of Earths and super-Earths embedded in inviscid disks, confirming their slow/stalled migration even under gas-rich conditions, and showing that disk transport rates range up to $\sim$$10^{-7} M_\odot~{\rm yr^{-1}}$ and scale as $\dot{M} \propto \Sigma M_{\rm p}^{3/2}$, where $\Sigma$ is the disk surface density and $M_{\rm p}$ is the planet mass. Gas initially sandwiched between two planets is torqued past both into the inner and outer disks. In sum, sufficiently compact systems of super-Earths can clear their natal disk gas, in a dispersal history that may be complicated and non-steady, but which conceivably leads over Myr timescales to large gas depletions similar to those characterizing transition disks.

## Full text

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## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/1701.08161/full.md

## References

57 references — full list in the complete paper: https://tomesphere.com/paper/1701.08161/full.md

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Source: https://tomesphere.com/paper/1701.08161