# Structure and Evolution of Internally Heated Hot Jupiters

**Authors:** Thaddeus D. Komacek, Andrew N. Youdin

arXiv: 1706.07605 · 2020-05-05

## TL;DR

This study models the internal heating of hot Jupiters, showing that deeper and more intense heating can explain their observed large radii, with implications for understanding their thermal evolution.

## Contribution

It systematically explores the effects of varying depth and intensity of internal heating on hot Jupiter radii without assuming specific heating mechanisms.

## Key findings

- Deeper heating at 100 bars explains observed radii with only 1% of stellar irradiation.
- Shallow heating at 1-10 bars is ineffective unless very intense.
- Heating at 10^4 bars suppresses cooling as effectively as core heating.

## Abstract

Hot Jupiters receive strong stellar irradiation, producing equilibrium temperatures of $1000 - 2500 \ \mathrm{Kelvin}$. Incoming irradiation directly heats just their thin outer layer, down to pressures of $\sim 0.1 \ \mathrm{bars}$. In standard irradiated evolution models of hot Jupiters, predicted transit radii are too small. Previous studies have shown that deeper heating -- at a small fraction of the heating rate from irradiation -- can explain observed radii. Here we present a suite of evolution models for HD 209458b where we systematically vary both the depth and intensity of internal heating, without specifying the uncertain heating mechanism(s). Our models start with a hot, high entropy planet whose radius decreases as the convective interior cools. The applied heating suppresses this cooling. We find that very shallow heating -- at pressures of $1 - 10 \ \mathrm{bars}$ -- does not significantly suppress cooling, unless the total heating rate is $\gtrsim 10\%$ of the incident stellar power. Deeper heating, at $100 \ \mathrm{bars}$, requires heating at only $1\%$ of the stellar irradiation to explain the observed transit radius of $1.4 R_{\rm Jup}$ after 5 Gyr of cooling. In general, more intense and deeper heating results in larger hot Jupiter radii. Surprisingly, we find that heat deposited at $10^4 \ \mathrm{bars}$ -- which is exterior to $\approx 99\%$ of the planet's mass -- suppresses planetary cooling as effectively as heating at the center. In summary, we find that relatively shallow heating is required to explain the radii of most hot Jupiters, provided that this heat is applied early and persists throughout their evolution.

## Full text

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## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/1706.07605/full.md

## References

72 references — full list in the complete paper: https://tomesphere.com/paper/1706.07605/full.md

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Source: https://tomesphere.com/paper/1706.07605