The stable climate of KELT-9b

K. Jones; B. M. Morris; B. O. Demory; K. Heng; M. J. Hooton; N. Billot; D. Ehrenreich; S. Hoyer; A. E. Simon; M. Lendl; O. D.S. Demangeon; S. G. Sousa; A. Bonfanti; T. G. Wilson; S. Salmon; Sz Csizmadia; H. Parviainen; G. Bruno; Y. Alibert; R. Alonso; G. Anglada; T. Bárczy; D. Barrado; S. C.C. Barros; W. Baumjohann; M. Beck; T. Beck; W. Benz; X. Bonfils; A. Brandeker; C. Broeg; J. Cabrera; S. Charnoz; A. Collier Cameron; M. B. Davies; M. Deleuil; A. Deline; L. Delrez; A. Erikson; A. Fortier; L. Fossati; M. Fridlund; D. Gandolfi; M. Gillon; M. Güdel; K. G. Isaak; L. L. Kiss; J. Laskar; A. Lecavelier Des Etangs; C. Lovis; D. Magrin; P. F.L. Maxted; V. Nascimbeni; G. Olofsson; R. Ottensamer; I. Pagano; E. Pallé; G. Peter; G. Piotto; D. Pollacco; D. Queloz; R. Ragazzoni; N. Rando; F. Ratti; H. Rauer; C. Reimers; I. Ribas; N. C. Santos; G. Scandariato; D. Ségransan; A. M.S. Smith; M. Steller; Gy M. Szabó; N. Thomas; S. Udry; V. Van Grootel; I. Walter; N. A. Walton; W. Wang Jungo

doi:10.1051/0004-6361/202243823

The stable climate of KELT-9b

K. Jones
, B. M. Morris
, B. O. Demory
, K. Heng
, M. J. Hooton
, N. Billot
, D. Ehrenreich
, S. Hoyer
, A. E. Simon
, M. Lendl
, O. D.S. Demangeon
, S. G. Sousa
, A. Bonfanti
, T. G. Wilson
, S. Salmon
, Sz Csizmadia
, H. Parviainen
, G. Bruno
, Y. Alibert
, R. Alonso

G. Anglada, T. Bárczy, D. Barrado, S. C.C. Barros, W. Baumjohann, M. Beck, T. Beck, W. Benz, X. Bonfils, A. Brandeker, C. Broeg, J. Cabrera, S. Charnoz, A. Collier Cameron, M. B. Davies, M. Deleuil, A. Deline, L. Delrez, A. Erikson, A. Fortier, L. Fossati, M. Fridlund, D. Gandolfi, M. Gillon, M. Güdel, K. G. Isaak, L. L. Kiss, J. Laskar, A. Lecavelier Des Etangs, C. Lovis, D. Magrin, P. F.L. Maxted, V. Nascimbeni, G. Olofsson, R. Ottensamer, I. Pagano, E. Pallé, G. Peter, G. Piotto, D. Pollacco, D. Queloz, R. Ragazzoni, N. Rando, F. Ratti, H. Rauer, C. Reimers, I. Ribas, N. C. Santos, G. Scandariato, D. Ségransan, A. M.S. Smith, M. Steller, Gy M. Szabó, N. Thomas, S. Udry, V. Van Grootel, I. Walter, N. A. Walton, W. Wang Jungo

University of Bern
University of Warwick
University of Cambridge
Université de Genève
University of Geneva
LAM
Ipatimup Diagnósticos
Space Research Institute
University of St Andrews
DLR
Instituto de Astrofisica de Canarias
INAF Osservatorio Astrofisico di Catania
Research Unit; CIBERNED and Universidad de La Laguna
Campus UAB
Institut d’Estudis Espacials de Catalunya (IEEC)
Admatis Ltd.
ESAC campus
Université Grenoble Alpes
Stockholm University
Université Paris Diderot
Lund University
University of Liège
University of Leiden
Onsala Space Observatory
University of Turin
University of Vienna
ESTEC - European Space Research and Technology Centre
Konkoly Observatory
Eötvös Loránd University
Sorbonne Univ.
Institut d’Astrophysique de Paris
INAF Osservatorio Astronomico di Padova
Keele University
University of Padova
ETH Zurich
TU Berlin
Free University of Berlin
Institute of Astronomy

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Even among the most irradiated gas giants, so-called ultra-hot Jupiters, KELT-9b stands out as the hottest planet thus far discovered with a dayside temperature of over 4500 K. At these extreme irradiation levels, we expect an increase in heat redistribution efficiency and a low Bond albedo owed to an extended atmosphere with molecular hydrogen dissociation occurring on the planetary dayside. We present new photometric observations of the KELT-9 system throughout 4 full orbits and 9 separate occultations obtained by the 30 cm space telescope CHEOPS. The CHEOPS bandpass, located at optical wavelengths, captures the peak of the thermal emission spectrum of KELT-9b. In this work we simultaneously analyse CHEOPS phase curves along with public phase curves from TESS and Spitzer to infer joint constraints on the phase curve variation, gravity-darkened transits, and occultation depth in three bandpasses, as well as derive 2D temperature maps of the atmosphere at three different depths. We find a day-night heat redistribution efficiency of ∼0.3 which confirms expectations of enhanced energy transfer to the planetary nightside due to dissociation and recombination of molecular hydrogen. We also calculate a Bond albedo consistent with zero.

langue originale	Anglais
Numéro d'article	A118
journal	Astronomy and Astrophysics
Volume	666
Les DOIs	https://doi.org/10.1051/0004-6361/202243823
état	Publié - 1 oct. 2022
Modification externe	Oui

Accès au document

10.1051/0004-6361/202243823

Autres fichiers et liens

Lien vers la publication dans Scopus

Contient cette citation

Jones, K., Morris, B. M., Demory, B. O., Heng, K., Hooton, M. J., Billot, N., Ehrenreich, D., Hoyer, S., Simon, A. E., Lendl, M., Demangeon, O. D. S., Sousa, S. G., Bonfanti, A., Wilson, T. G., Salmon, S., Csizmadia, S., Parviainen, H., Bruno, G., Alibert, Y., ... Wang Jungo, W. (2022). The stable climate of KELT-9b. Astronomy and Astrophysics, 666, Article A118. https://doi.org/10.1051/0004-6361/202243823

@article{c14d9f7f71ea46d2b8395a9ec8a597f9,

title = "The stable climate of KELT-9b",

abstract = "Even among the most irradiated gas giants, so-called ultra-hot Jupiters, KELT-9b stands out as the hottest planet thus far discovered with a dayside temperature of over 4500 K. At these extreme irradiation levels, we expect an increase in heat redistribution efficiency and a low Bond albedo owed to an extended atmosphere with molecular hydrogen dissociation occurring on the planetary dayside. We present new photometric observations of the KELT-9 system throughout 4 full orbits and 9 separate occultations obtained by the 30 cm space telescope CHEOPS. The CHEOPS bandpass, located at optical wavelengths, captures the peak of the thermal emission spectrum of KELT-9b. In this work we simultaneously analyse CHEOPS phase curves along with public phase curves from TESS and Spitzer to infer joint constraints on the phase curve variation, gravity-darkened transits, and occultation depth in three bandpasses, as well as derive 2D temperature maps of the atmosphere at three different depths. We find a day-night heat redistribution efficiency of ∼0.3 which confirms expectations of enhanced energy transfer to the planetary nightside due to dissociation and recombination of molecular hydrogen. We also calculate a Bond albedo consistent with zero.",

keywords = "Eclipses, Instrumentation: photometers, Occultations, Planets and satellites: atmospheres, Planets and satellites: gaseous planets, Techniques: photometric",

author = "K. Jones and Morris, \{B. M.\} and Demory, \{B. O.\} and K. Heng and Hooton, \{M. J.\} and N. Billot and D. Ehrenreich and S. Hoyer and Simon, \{A. E.\} and M. Lendl and Demangeon, \{O. D.S.\} and Sousa, \{S. G.\} and A. Bonfanti and Wilson, \{T. G.\} and S. Salmon and Sz Csizmadia and H. Parviainen and G. Bruno and Y. Alibert and R. Alonso and G. Anglada and T. B{\'a}rczy and D. Barrado and Barros, \{S. C.C.\} and W. Baumjohann and M. Beck and T. Beck and W. Benz and X. Bonfils and A. Brandeker and C. Broeg and J. Cabrera and S. Charnoz and \{Collier Cameron\}, A. and Davies, \{M. B.\} and M. Deleuil and A. Deline and L. Delrez and A. Erikson and A. Fortier and L. Fossati and M. Fridlund and D. Gandolfi and M. Gillon and M. G{\"u}del and Isaak, \{K. G.\} and Kiss, \{L. L.\} and J. Laskar and \{Lecavelier Des Etangs\}, A. and C. Lovis and D. Magrin and Maxted, \{P. F.L.\} and V. Nascimbeni and G. Olofsson and R. Ottensamer and I. Pagano and E. Pall{\'e} and G. Peter and G. Piotto and D. Pollacco and D. Queloz and R. Ragazzoni and N. Rando and F. Ratti and H. Rauer and C. Reimers and I. Ribas and Santos, \{N. C.\} and G. Scandariato and D. S{\'e}gransan and Smith, \{A. M.S.\} and M. Steller and Szab{\'o}, \{Gy M.\} and N. Thomas and S. Udry and \{Van Grootel\}, V. and I. Walter and Walton, \{N. A.\} and \{Wang Jungo\}, W.",

year = "2022",

month = oct,

day = "1",

doi = "10.1051/0004-6361/202243823",

language = "English",

volume = "666",

journal = "Astronomy and Astrophysics",

issn = "0004-6361",

}

Jones, K, Morris, BM, Demory, BO, Heng, K, Hooton, MJ, Billot, N, Ehrenreich, D, Hoyer, S, Simon, AE, Lendl, M, Demangeon, ODS, Sousa, SG, Bonfanti, A, Wilson, TG, Salmon, S, Csizmadia, S, Parviainen, H, Bruno, G, Alibert, Y, Alonso, R, Anglada, G, Bárczy, T, Barrado, D, Barros, SCC, Baumjohann, W, Beck, M, Beck, T, Benz, W, Bonfils, X, Brandeker, A, Broeg, C, Cabrera, J, Charnoz, S, Collier Cameron, A, Davies, MB, Deleuil, M, Deline, A, Delrez, L, Erikson, A, Fortier, A, Fossati, L, Fridlund, M, Gandolfi, D, Gillon, M, Güdel, M, Isaak, KG, Kiss, LL, Laskar, J, Lecavelier Des Etangs, A, Lovis, C, Magrin, D, Maxted, PFL, Nascimbeni, V, Olofsson, G, Ottensamer, R, Pagano, I, Pallé, E, Peter, G, Piotto, G, Pollacco, D, Queloz, D, Ragazzoni, R, Rando, N, Ratti, F, Rauer, H, Reimers, C, Ribas, I, Santos, NC, Scandariato, G, Ségransan, D, Smith, AMS, Steller, M, Szabó, GM, Thomas, N, Udry, S, Van Grootel, V, Walter, I, Walton, NA & Wang Jungo, W 2022, 'The stable climate of KELT-9b', Astronomy and Astrophysics, VOL. 666, A118. https://doi.org/10.1051/0004-6361/202243823

TY - JOUR

T1 - The stable climate of KELT-9b

AU - Jones, K.

AU - Morris, B. M.

AU - Demory, B. O.

AU - Heng, K.

AU - Hooton, M. J.

AU - Billot, N.

AU - Ehrenreich, D.

AU - Hoyer, S.

AU - Simon, A. E.

AU - Lendl, M.

AU - Demangeon, O. D.S.

AU - Sousa, S. G.

AU - Bonfanti, A.

AU - Wilson, T. G.

AU - Salmon, S.

AU - Csizmadia, Sz

AU - Parviainen, H.

AU - Bruno, G.

AU - Alibert, Y.

AU - Alonso, R.

AU - Anglada, G.

AU - Bárczy, T.

AU - Barrado, D.

AU - Barros, S. C.C.

AU - Baumjohann, W.

AU - Beck, M.

AU - Beck, T.

AU - Benz, W.

AU - Bonfils, X.

AU - Brandeker, A.

AU - Broeg, C.

AU - Cabrera, J.

AU - Charnoz, S.

AU - Collier Cameron, A.

AU - Davies, M. B.

AU - Deleuil, M.

AU - Deline, A.

AU - Delrez, L.

AU - Erikson, A.

AU - Fortier, A.

AU - Fossati, L.

AU - Fridlund, M.

AU - Gandolfi, D.

AU - Gillon, M.

AU - Güdel, M.

AU - Isaak, K. G.

AU - Kiss, L. L.

AU - Laskar, J.

AU - Lecavelier Des Etangs, A.

AU - Lovis, C.

AU - Magrin, D.

AU - Maxted, P. F.L.

AU - Nascimbeni, V.

AU - Olofsson, G.

AU - Ottensamer, R.

AU - Pagano, I.

AU - Pallé, E.

AU - Peter, G.

AU - Piotto, G.

AU - Pollacco, D.

AU - Queloz, D.

AU - Ragazzoni, R.

AU - Rando, N.

AU - Ratti, F.

AU - Rauer, H.

AU - Reimers, C.

AU - Ribas, I.

AU - Santos, N. C.

AU - Scandariato, G.

AU - Ségransan, D.

AU - Smith, A. M.S.

AU - Steller, M.

AU - Szabó, Gy M.

AU - Thomas, N.

AU - Udry, S.

AU - Van Grootel, V.

AU - Walter, I.

AU - Walton, N. A.

AU - Wang Jungo, W.

PY - 2022/10/1

Y1 - 2022/10/1

N2 - Even among the most irradiated gas giants, so-called ultra-hot Jupiters, KELT-9b stands out as the hottest planet thus far discovered with a dayside temperature of over 4500 K. At these extreme irradiation levels, we expect an increase in heat redistribution efficiency and a low Bond albedo owed to an extended atmosphere with molecular hydrogen dissociation occurring on the planetary dayside. We present new photometric observations of the KELT-9 system throughout 4 full orbits and 9 separate occultations obtained by the 30 cm space telescope CHEOPS. The CHEOPS bandpass, located at optical wavelengths, captures the peak of the thermal emission spectrum of KELT-9b. In this work we simultaneously analyse CHEOPS phase curves along with public phase curves from TESS and Spitzer to infer joint constraints on the phase curve variation, gravity-darkened transits, and occultation depth in three bandpasses, as well as derive 2D temperature maps of the atmosphere at three different depths. We find a day-night heat redistribution efficiency of ∼0.3 which confirms expectations of enhanced energy transfer to the planetary nightside due to dissociation and recombination of molecular hydrogen. We also calculate a Bond albedo consistent with zero.

AB - Even among the most irradiated gas giants, so-called ultra-hot Jupiters, KELT-9b stands out as the hottest planet thus far discovered with a dayside temperature of over 4500 K. At these extreme irradiation levels, we expect an increase in heat redistribution efficiency and a low Bond albedo owed to an extended atmosphere with molecular hydrogen dissociation occurring on the planetary dayside. We present new photometric observations of the KELT-9 system throughout 4 full orbits and 9 separate occultations obtained by the 30 cm space telescope CHEOPS. The CHEOPS bandpass, located at optical wavelengths, captures the peak of the thermal emission spectrum of KELT-9b. In this work we simultaneously analyse CHEOPS phase curves along with public phase curves from TESS and Spitzer to infer joint constraints on the phase curve variation, gravity-darkened transits, and occultation depth in three bandpasses, as well as derive 2D temperature maps of the atmosphere at three different depths. We find a day-night heat redistribution efficiency of ∼0.3 which confirms expectations of enhanced energy transfer to the planetary nightside due to dissociation and recombination of molecular hydrogen. We also calculate a Bond albedo consistent with zero.

KW - Eclipses

KW - Instrumentation: photometers

KW - Occultations

KW - Planets and satellites: atmospheres

KW - Planets and satellites: gaseous planets

KW - Techniques: photometric

UR - https://www.scopus.com/pages/publications/85166667721

U2 - 10.1051/0004-6361/202243823

DO - 10.1051/0004-6361/202243823

M3 - Article

AN - SCOPUS:85166667721

SN - 0004-6361

VL - 666

JO - Astronomy and Astrophysics

JF - Astronomy and Astrophysics

M1 - A118

ER -

The stable climate of KELT-9b

Résumé

Accès au document

Autres fichiers et liens

Empreinte digitale

Contient cette citation