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Published March 2023 | Published
Journal Article Open

Characterization of a Set of Small Planets with TESS and CHEOPS and an Analysis of Photometric Performance

Oddo, Dominic ORCID icon
Dragomir, Diana ORCID icon
Brandeker, Alexis ORCID icon
Osborn, Hugh P. ORCID icon
Collins, Karen ORCID icon
Stassun, Keivan G. ORCID icon
Astudillo-Defru, Nicola ORCID icon
Bieryla, Allyson ORCID icon
Howell, Steve B. ORCID icon
Ciardi, David R. ORCID icon
Quinn, Samuel ORCID icon
Almenara, Jose M. ORCID icon
Briceño, César ORCID icon
Collins, Kevin I. ORCID icon
Colón, Knicole D. ORCID icon
Conti, Dennis M. ORCID icon
Crouzet, Nicolas ORCID icon
Furlan, Elise ORCID icon
Gan, Tianjun ORCID icon
Gnilka, Crystal L. ORCID icon
Goeke, Robert F. ORCID icon
Gonzales, Erica ORCID icon
Harris, Mallory
Jenkins, Jon M. ORCID icon
Jensen, Eric L. N. ORCID icon
Latham, David ORCID icon
Law, Nicholas ORCID icon
Lund, Michael B. ORCID icon
Mann, Andrew W. ORCID icon
Massey, Bob ORCID icon
Murgas, Felipe ORCID icon
Ricker, George ORCID icon
Relles, Howard M.
Rowden, Pamela ORCID icon
Schwarz, Richard P. ORCID icon
Schlieder, Joshua ORCID icon
Shporer, Avi ORCID icon
Seager, Sara ORCID icon
Srdoc, Gregor
Torres, Guillermo ORCID icon
Twicken, Joseph D. ORCID icon
Vanderspek, Roland ORCID icon
Winn, Joshua N. ORCID icon
Ziegler, Carl

Abstract

The radius valley carries implications for how the atmospheres of small planets form and evolve, but this feature is visible only with highly precise characterizations of many small planets. We present the characterization of nine planets and one planet candidate with both NASA TESS and ESA CHEOPS observations, which adds to the overall population of planets bordering the radius valley. While five of our planets—TOI 118 b, TOI 262 b, TOI 455 b, TOI 560 b, and TOI 562 b—have already been published, we vet and validate transit signals as planetary using follow-up observations for four new TESS planets, including TOI 198 b, TOI 244 b, TOI 444 b, and TOI 470 b. While a three times increase in primary mirror size should mean that one CHEOPS transit yields an equivalent model uncertainty in transit depth as about nine TESS transits in the case that the star is equally as bright in both bands, we find that our CHEOPS transits typically yield uncertainties equivalent to between two and 12 TESS transits, averaging 5.9 equivalent transits. Therefore, we find that while our fits to CHEOPS transits provide overall lower uncertainties on transit depth and better precision relative to fits to TESS transits, our uncertainties for these fits do not always match expected predictions given photon-limited noise. We find no correlations between number of equivalent transits and any physical parameters, indicating that this behavior is not strictly systematic, but rather might be due to other factors such as in-transit gaps during CHEOPS visits or nonhomogeneous detrending of CHEOPS light curves.

Additional Information

© 2023. The Author(s). Published by the American Astronomical Society. Original content from this work may be used under the terms of the Creative Commons Attribution 4.0 licence. Any further distribution of this work must maintain attribution to the author(s) and the title of the work, journal citation and DOI. We graciously thank the anonymous referee and data editor, who both provided valuable feedback on this publication. D.D. acknowledges support from the TESS Guest Investigator Program grants 80NSSC21K0108 and 80NSSC22K0185. We acknowledge contributions from Thomas G. Wilson, Andrea Fortier, and other members of the CHEOPS GTO team, regarding estimation of noise in CHEOPS light curves and comparisons to other systems observed by CHEOPS. This paper includes data collected by the TESS mission. Funding for the TESS mission is provided by NASA's Science Mission Directorate. We acknowledge the use of public TESS data from pipelines at the TESS Science Office and at the TESS Science Processing Operations Center. Resources supporting this work were provided by the NASA High-End Computing (HEC) Program through the NASA Advanced Supercomputing (NAS) Division at Ames Research Center for the production of the SPOC data products. Some/all of the data presented in this paper were obtained from the Mikulski Archive for Space Telescopes (MAST) at the Space Telescope Science Institute. The specific observations analyzed can be accessed via doi:10.17909/dshz-jz09 . This work makes use of observations from the LCOGT network. Part of the LCOGT telescope time was granted by NOIRLab through the Mid-Scale Innovations Program (MSIP). MSIP is funded by NSF. This research has made use of the NASA Exoplanet Archive, which is operated by the California Institute of Technology, under contract with the National Aeronautics and Space Administration under the Exoplanet Exploration Program. This research made use of Lightkurve, a Python package for Kepler and TESS data analysis (Lightkurve Collaboration et al.2018). Some of the observations in the paper made use of the High-Resolution Imaging instruments 'Alopeke and Zorro obtained under Gemini LLP Proposal Number: GN/S-2021A-LP-105. 'Alopeke and Zorro were funded by the NASA Exoplanet Exploration Program and built at the NASA Ames Research Center by Steve B. Howell, Nic Scott, Elliott P. Horch, and Emmett Quigley. 'Alopeke (Zorro) was mounted on the Gemini North (South) telescope of the international Gemini Observatory, a program of NSF's OIR Lab, which is managed by the Association of Universities for Research in Astronomy (AURA) under a cooperative agreement with the National Science Foundation on behalf of the Gemini partnership: the National Science Foundation (United States), National Research Council (Canada), Agencia Nacional de Investigación y Desarrollo (Chile), Ministerio de Ciencia, Tecnologóa e Innovación (Argentina), Ministério da Ciência, Tecnologia, Inovações e Comunicações (Brazil), and Korea Astronomy and Space Science Institute (Republic of Korea). Facilities: TESS - , CHEOPS - , LCOGT - , VLT-ESPRESSO - , CTIO/SMARTS-CHIRON - , FLWO-TRES - , Gemini-'Alopeke/Zorro - , Keck2-NIRC2 - , Palomar-PHARO - , SOAR-HRCam. - Software: AstroImageJ (Collins et al. 2017), astropy (Astropy Collaboration et al. 2013, 2018, 2022), numpy (Harris et al. 2020), matplotlib (Hunter 2007), lightkurve (Lightkurve Collaboration et al. 2018), pycheops (Maxted et al. 2022), PyLDTK (Parviainen & Aigrain 2015), juliet (Espinoza et al. 2019), emcee (Foreman-Mackey et al. 2013), batman (Kreidberg 2015), corner (Foreman-Mackey 2016), MRExo (Kanodia et al. 2019), TAPIR (Jensen 2013).

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Additional details

Identifiers Funding Dates Caltech Custom Metadata
Created:
August 22, 2023
Modified:
October 18, 2023