Enhanced thermal radiation from a tidally heated exomoon with a single hot spot. (arXiv:2110.05353v1 [astro-ph.EP])

Enhanced thermal radiation from a tidally heated exomoon with a single hot spot. (arXiv:2110.05353v1 [astro-ph.EP])
<a href="http://arxiv.org/find/astro-ph/1/au:+Jager_Z/0/1/0/all/0/1">Zolt&#xe1;n J&#xe4;ger</a>, <a href="http://arxiv.org/find/astro-ph/1/au:+Szabo_G/0/1/0/all/0/1">Gyula M Szab&#xf3;</a>

An exomoon on a non perfectly circular orbit experiences tidal heating that
is capable to significantly contribute to the thermal

brightness of the moon. Here we argue that the thermal heat is unevenly
distributed on the moon’s surface,

the emission of the tidal heat is limited to a few hot spots on the surface.

A well-known example is the tidally heated Io. Due to their significantly
increased temperature,

the hot spots enhance the energy emission in thermal wavelengths.

We made simulations using Monte-Carlo method to examine this contribution,

and to predict about the possible detectability of such a spotted exomoon.

We found that in the case of large, Earth sized companions to jupiters around
red dwarf stars exhibit

a thermal flux that enables the direct detection of the moon,

due to its photometric signal that can exceed $approx$100 ppm in the most
favourable configurations.

An exomoon on a non perfectly circular orbit experiences tidal heating that
is capable to significantly contribute to the thermal

brightness of the moon. Here we argue that the thermal heat is unevenly
distributed on the moon’s surface,

the emission of the tidal heat is limited to a few hot spots on the surface.

A well-known example is the tidally heated Io. Due to their significantly
increased temperature,

the hot spots enhance the energy emission in thermal wavelengths.

We made simulations using Monte-Carlo method to examine this contribution,

and to predict about the possible detectability of such a spotted exomoon.

We found that in the case of large, Earth sized companions to jupiters around
red dwarf stars exhibit

a thermal flux that enables the direct detection of the moon,

due to its photometric signal that can exceed $approx$100 ppm in the most
favourable configurations.

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