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author Challener, Ryan C.
Mansfield, Megan Weiner
Cubillos, Patricio E.
Piette, Anjali A. A.
Coulombe, Louis-Philippe
Beltz, Hayley
Blecic, Jasmina
Rauscher, Emily
Bean, Jacob L.
Benneke, Björn
Kempton, Eliza M. -R.
Harrington, Joseph
Komacek, Thaddeus D.
Parmentier, Vivien
Casewell, S. L.
Iro, Nicolas
Mancini, Luigi
Nixon, Matthew C.
Radica, Michael
Steinrueck, Maria E.
Welbanks, Luis
Batalha, Natalie M.
Caceres, Claudio
Crossfield, Ian J. M.
Crouzet, Nicolas
Désert, Jean-Michel
Molaverdikhani, Karan
Nikolov, Nikolay K.
Palle, Enric
Rackham, Benjamin V.
Schlawin, Everett
Sing, David K.
Stevenson, Kevin B.
Tan, Xianyu
Turner, Jake D.
Zhang, Xi
author_facet Challener, Ryan C.
Mansfield, Megan Weiner
Cubillos, Patricio E.
Piette, Anjali A. A.
Coulombe, Louis-Philippe
Beltz, Hayley
Blecic, Jasmina
Rauscher, Emily
Bean, Jacob L.
Benneke, Björn
Kempton, Eliza M. -R.
Harrington, Joseph
Komacek, Thaddeus D.
Parmentier, Vivien
Casewell, S. L.
Iro, Nicolas
Mancini, Luigi
Nixon, Matthew C.
Radica, Michael
Steinrueck, Maria E.
Welbanks, Luis
Batalha, Natalie M.
Caceres, Claudio
Crossfield, Ian J. M.
Crouzet, Nicolas
Désert, Jean-Michel
Molaverdikhani, Karan
Nikolov, Nikolay K.
Palle, Enric
Rackham, Benjamin V.
Schlawin, Everett
Sing, David K.
Stevenson, Kevin B.
Tan, Xianyu
Turner, Jake D.
Zhang, Xi
contents Highly-irradiated giant exoplanets known as "ultra-hot Jupiters" are anticipated to exhibit large variations of atmospheric temperature and chemistry as a function of longitude, latitude, and altitude. Previous observations have hinted at these variations, but the existing data have been fundamentally restricted to probing hemisphere-integrated spectra, thereby providing only coarse information on atmospheric gradients. Here we present a spectroscopic eclipse map of an extrasolar planet, resolving the atmosphere in multiple dimensions simultaneously. We analyze a secondary eclipse of the ultra-hot Jupiter WASP-18b observed with the NIRISS instrument on JWST. The mapping reveals weaker longitudinal temperature gradients than were predicted by theoretical models, indicating the importance of hydrogen dissociation and/or nightside clouds in shaping global thermal emission. Additionally, we identify two thermally distinct regions of the planet's atmosphere: a "hotspot" surrounding the substellar point and a "ring" near the dayside limbs. The hotspot region shows a strongly inverted thermal structure due to the presence of optical absorbers and a water abundance marginally lower than the hemispheric average, in accordance with theoretical predictions. The ring region shows colder temperatures and poorly constrained chemical abundances. Similar future analyses will reveal three-dimensional thermal, chemical, and dynamical properties of a broad range of exoplanet atmospheres.
format Preprint
id arxiv_https___arxiv_org_abs_2510_24708
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Horizontal and vertical exoplanet thermal structure from a JWST spectroscopic eclipse map
Challener, Ryan C.
Mansfield, Megan Weiner
Cubillos, Patricio E.
Piette, Anjali A. A.
Coulombe, Louis-Philippe
Beltz, Hayley
Blecic, Jasmina
Rauscher, Emily
Bean, Jacob L.
Benneke, Björn
Kempton, Eliza M. -R.
Harrington, Joseph
Komacek, Thaddeus D.
Parmentier, Vivien
Casewell, S. L.
Iro, Nicolas
Mancini, Luigi
Nixon, Matthew C.
Radica, Michael
Steinrueck, Maria E.
Welbanks, Luis
Batalha, Natalie M.
Caceres, Claudio
Crossfield, Ian J. M.
Crouzet, Nicolas
Désert, Jean-Michel
Molaverdikhani, Karan
Nikolov, Nikolay K.
Palle, Enric
Rackham, Benjamin V.
Schlawin, Everett
Sing, David K.
Stevenson, Kevin B.
Tan, Xianyu
Turner, Jake D.
Zhang, Xi
Earth and Planetary Astrophysics
Highly-irradiated giant exoplanets known as "ultra-hot Jupiters" are anticipated to exhibit large variations of atmospheric temperature and chemistry as a function of longitude, latitude, and altitude. Previous observations have hinted at these variations, but the existing data have been fundamentally restricted to probing hemisphere-integrated spectra, thereby providing only coarse information on atmospheric gradients. Here we present a spectroscopic eclipse map of an extrasolar planet, resolving the atmosphere in multiple dimensions simultaneously. We analyze a secondary eclipse of the ultra-hot Jupiter WASP-18b observed with the NIRISS instrument on JWST. The mapping reveals weaker longitudinal temperature gradients than were predicted by theoretical models, indicating the importance of hydrogen dissociation and/or nightside clouds in shaping global thermal emission. Additionally, we identify two thermally distinct regions of the planet's atmosphere: a "hotspot" surrounding the substellar point and a "ring" near the dayside limbs. The hotspot region shows a strongly inverted thermal structure due to the presence of optical absorbers and a water abundance marginally lower than the hemispheric average, in accordance with theoretical predictions. The ring region shows colder temperatures and poorly constrained chemical abundances. Similar future analyses will reveal three-dimensional thermal, chemical, and dynamical properties of a broad range of exoplanet atmospheres.
title Horizontal and vertical exoplanet thermal structure from a JWST spectroscopic eclipse map
topic Earth and Planetary Astrophysics
url https://arxiv.org/abs/2510.24708