TY - JOUR
T1 - Precise constraints on the energy budget of WASP-121 b from its JWST NIRISS/SOSS phase curve
AU - Splinter, Jared
AU - Coulombe, Louis-Philippe
AU - Frazier, Robert C.
AU - Cowan, Nicolas B.
AU - Rauscher, Emily
AU - Dang, Lisa
AU - Radica, Michael
AU - Collins, Sean
AU - Pelletier, Stefan
AU - Allart, Romain
AU - MacDonald, Ryan J.
AU - Lafrenière, David
AU - Albert, Loïc
AU - Benneke, Björn
AU - Doyon, René
AU - Jayawardhana, Ray
AU - Johnstone, Doug
AU - Krishnamurthy, Vigneshwaran
AU - Piaulet-Ghorayeb, Caroline
AU - Kaltnegger, Lisa
AU - Meyer, Michael R.
AU - Taylor, Jake
AU - Turner, Jake D.
N1 - Funding: This project was undertaken with the financial support of the Canadian Space Agency through a NEAT/GTO grant. The contributions from RF were supported in part by grant #2019-1403 from the Heising-Simons Foundation. N.B.C. acknowledges support from an NSERC Discovery Grant, a Tier 2 Canada Research Chair, and an Arthur B. McDonald Fellowship and thanks the Trottier Space Institute and l’Institut de recherche sur les exoplanétes for their financial support and dynamic intellectual environment. L.D. is a Banting and Trottier Postdoctoral Fellow and acknowledges support from the Natural Sciences and Engineering Research Council (NSERC) and the Trottier Family Foundation. S.P. acknowledges support from the Swiss National Science Foundation under grant 51NF40_205606 within the framework of the National Centre of Competence in Research PlanetS. R.J.M. is supported by NASA through the NASA Hubble Fellowship grant HST-HF2-51513.001, awarded by the Space Telescope Science Institute, which is operated by the Association of Universities for Research in Astronomy, Inc., for NASA, under contract NAS 5-26555. D.L. acknowledges financial support from NSERC and FRQNT. C.P.-G. acknowledges support from the E. Margaret Burbidge Prize Postdoctoral Fellowship from the Brinson Foundation. J.D.T. acknowledges funding support by the TESS Guest Investigator Program G06165.
PY - 2025/12/1
Y1 - 2025/12/1
N2 - Ultra-hot Jupiters exhibit day-to-night temperature contrasts upwards of 1000 K due to competing effects of strong winds, short radiative timescales, magnetic drag, and H2 dissociation/recombination. Spectroscopic phase curves provide critical insights into these processes by mapping temperature distributions and constraining the planet’s energy budget across different pressure levels. Here, we present the first NIRISS/SOSS phase curve of an ultra-hot Jupiter, WASP-121 b. The instrument’s bandpass [0.6–2.85 μm] captures an estimated 50%–83% of the planet’s bolometric flux, depending on orbital phase, allowing for unprecedented constraints on the planet’s global energy budget; previous measurements with HST/WFC3 and JWST/NIRSpec/G395H captured roughly 20% of the planetary flux. Accounting for the unobserved regions of the spectrum, we estimate effective day- and nightside temperatures of Tday = 2717 ± 17 K and Tnight = 1562+18-19 K corresponding to a Bond albedo of AB = 0.277 ± 0.016 and a heat recirculation efficiency of ε = 0.246 ± 0.014. Matching the phase-dependent effective temperature with energy balance models yields a similar Bond albedo of 0.3 and a mixed layer pressure of 1 bar consistent with photospheric pressures, but unexpectedly slow winds of 0.2 km s−1, indicative of inefficient heat redistribution. The shorter optical wavelengths of the NIRISS/SOSS Order 2 yield a geometric albedo of Ag = 0.093+0.029-0.027 (3σ upper limit of 0.175), reinforcing the unexplained trend of hot Jupiters exhibiting larger Bond than geometric albedos. We also detect near-zero phase curve offsets for wavelengths above 1.5 μm, consistent with inefficient heat transport, while shorter wavelengths potentially sensitive to reflected light show eastward offsets.
AB - Ultra-hot Jupiters exhibit day-to-night temperature contrasts upwards of 1000 K due to competing effects of strong winds, short radiative timescales, magnetic drag, and H2 dissociation/recombination. Spectroscopic phase curves provide critical insights into these processes by mapping temperature distributions and constraining the planet’s energy budget across different pressure levels. Here, we present the first NIRISS/SOSS phase curve of an ultra-hot Jupiter, WASP-121 b. The instrument’s bandpass [0.6–2.85 μm] captures an estimated 50%–83% of the planet’s bolometric flux, depending on orbital phase, allowing for unprecedented constraints on the planet’s global energy budget; previous measurements with HST/WFC3 and JWST/NIRSpec/G395H captured roughly 20% of the planetary flux. Accounting for the unobserved regions of the spectrum, we estimate effective day- and nightside temperatures of Tday = 2717 ± 17 K and Tnight = 1562+18-19 K corresponding to a Bond albedo of AB = 0.277 ± 0.016 and a heat recirculation efficiency of ε = 0.246 ± 0.014. Matching the phase-dependent effective temperature with energy balance models yields a similar Bond albedo of 0.3 and a mixed layer pressure of 1 bar consistent with photospheric pressures, but unexpectedly slow winds of 0.2 km s−1, indicative of inefficient heat redistribution. The shorter optical wavelengths of the NIRISS/SOSS Order 2 yield a geometric albedo of Ag = 0.093+0.029-0.027 (3σ upper limit of 0.175), reinforcing the unexplained trend of hot Jupiters exhibiting larger Bond than geometric albedos. We also detect near-zero phase curve offsets for wavelengths above 1.5 μm, consistent with inefficient heat transport, while shorter wavelengths potentially sensitive to reflected light show eastward offsets.
KW - Exoplanets
KW - Exoplanet atmospheres
KW - Exoplanet atmospheric dynamics
KW - Exoplanet systems
KW - Exoplanet astronomy
KW - Exoplanet atmospheric structure
KW - Planetary atmospheres
U2 - 10.3847/1538-3881/ae0e52
DO - 10.3847/1538-3881/ae0e52
M3 - Article
SN - 0004-6256
VL - 170
JO - The Astronomical Journal
JF - The Astronomical Journal
IS - 6
M1 - 323
ER -