A new method to correct for host star variability in multi-epoch observations of exoplanet transmission spectra

TL;DR

This paper introduces a novel Gaussian Processes-based method to correct for stellar variability in multi-epoch exoplanet transmission spectra, improving the accuracy of atmospheric characterization for active stars like WASP-19b.

Contribution

The study presents a new correction technique for stellar variability effects in multi-epoch transmission spectra, validated on WASP-19b using GMOS data and TESS photometry.

Findings

Stellar variability affects transmission spectra at individual epochs.

The anticorrelation between spectral slopes and offsets matches model predictions.

Correcting for stellar variability reconciles conflicting previous measurements.

Abstract

Transmission spectra of exoplanets orbiting active stars suffer from wavelength-dependent effects due to stellar photospheric heterogeneity. WASP-19b, an ultra-hot Jupiter (T$_{eq}$ $\sim$ 2100 K), is one such strongly irradiated gas-giant orbiting an active solar-type star. We present optical (520-900 nm) transmission spectra of WASP-19b obtained across eight epochs using the Gemini Multi-Object Spectrograph (GMOS) on the Gemini-South telescope. We apply our recently developed Gaussian Processes regression based method to model the transit light curve systematics and extract the transmission spectrum at each epoch. We find that WASP-19b's transmission spectrum is affected by stellar variability at individual epochs. We report an observed anticorrelation between the relative slopes and offsets of the spectra across all epochs. This anticorrelation is consistent with the predictions from the forward transmission models, which account for the effect of unocculted stellar spots and faculae measured previously for WASP-19. We introduce a new method to correct for this stellar variability effect at each epoch by using the observed correlation between the transmission spectral slopes and offsets. We compare our stellar variability corrected GMOS transmission spectrum with previous contradicting MOS measurements for WASP-19b and attempt to reconcile them. We also measure the amplitude and timescale of broadband stellar variability of WASP-19 from TESS photometry, which we find to be consistent with the effect observed in GMOS spectroscopy and ground-based broadband photometric long-term monitoring. Our results ultimately caution against combining multi-epoch optical transmission spectra of exoplanets orbiting active stars before correcting each epoch for stellar variability.