# Analytic solutions to the maximum and average exoplanet transit depth   for common stellar limb darkening laws

**Authors:** Ren\'e Heller (Max Planck Institute for Solar System Research,, G\"ottingen, Germany)

arXiv: 1901.01730 · 2019-03-22

## TL;DR

This paper derives analytical formulas to accurately determine the true exoplanet transit depth and radius, accounting for stellar limb darkening effects across various limb darkening laws, improving upon the simple squared radius ratio approximation.

## Contribution

It provides new analytical solutions for transit depth overshoot due to limb darkening for arbitrary impact parameters and limb darkening laws, enabling more precise radius measurements without light curve fitting.

## Key findings

- Transit depth overshoot ranges from 15% to 30% depending on star type.
- Analytical solutions significantly reduce errors compared to small planet approximation.
- Formulas allow direct calculation of planet radius from transit data with high accuracy.

## Abstract

The depth of an exoplanetary transit in the light curve of a distant star is commonly approximated as the squared planet-to-star radius ratio, (R_p/R_s)^2. Stellar limb darkening, however, results in significantly deeper transits. Here we derive analytical solutions to the overshoot of the mid-transit depth caused by stellar limb darkening compared to the (R_p/R_s)^2 estimate for arbitrary transit impact parameters. In turn, this allows us to compute the true planet-to-star radius ratio from the transit depth for a given parameterization of a limb darkening law and for a known transit impact parameter. We calculate the maximum emerging specific stellar intensity covered by the planet in transit and derive analytic solutions for the transit depth overshoot. Solutions are presented for the linear, quadratic, square-root, logarithmic, and non-linear stellar limb darkening with arbitrary transit impact parameters. We also derive formulae to calculate the average intensity along the transit chord, which allows us to estimate the actual transit depth (and therefore R_p/R_s) from the mean in-transit flux. The transit depth overshoot of exoplanets compared to the (R_p/R_s)^2 estimate increases from about 15% for A main-sequence stars to roughly 20% for sun-like stars and some 30% for K and M stars. The error in our analytical solutions for R_p/R_s from the small planet approximation is orders of magnitude smaller than the uncertainties arising from typical noise in real light curves and from the uncertain limb darkening. Our equations can be used to predict with high accuracy the expected transit depth of extrasolar planets. The actual planet radius can be calculated from the measured transit depth or from the mean in-transit flux if the stellar limb darkening can be properly parameterized and if the transit impact parameter is known. Light curve fitting is not required.

## Full text

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## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/1901.01730/full.md

## References

20 references — full list in the complete paper: https://tomesphere.com/paper/1901.01730/full.md

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Source: https://tomesphere.com/paper/1901.01730