An irradiated-Jupiter analogue hotter than the Sun

Na’ama Hallakoun; Dan Maoz; Alina G. Istrate; Carles Badenes; Elmé Breedt; Boris T. Gänsicke; Saurabh W. Jha; Bruno Leibundgut; Filippo Mannucci; Thomas R. Marsh; Gijs Nelemans; Ferdinando Patat; Alberto Rebassa-Mansergas

doi:10.1038/s41550-023-02048-z

An irradiated-Jupiter analogue hotter than the Sun

Na’ama Hallakoun^*, Dan Maoz, Alina G. Istrate, Carles Badenes, Elmé Breedt, Boris T. Gänsicke, Saurabh W. Jha, Bruno Leibundgut, Filippo Mannucci, Thomas R. Marsh, Gijs Nelemans, Ferdinando Patat, Alberto Rebassa-Mansergas

^*Corresponding author for this work

School of Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Planets orbiting close to hot stars experience intense extreme-ultraviolet radiation, potentially leading to atmosphere evaporation and to thermal dissociation of molecules. However, this extreme regime remains mainly unexplored due to observational challenges. Only a single known ultra-hot giant planet, KELT-9b, receives enough ultraviolet radiation for molecular dissociation, with a day-side temperature of ~4,600 K. An alternative approach uses irradiated brown dwarfs as hot-Jupiter analogues. With atmospheres and radii similar to those of giant planets, brown dwarfs orbiting close to hot Earth-sized white dwarf stars can be directly detected above the glare of the star. Here we report observations revealing an extremely irradiated low-mass companion to the hot white dwarf WD 0032–317. Our analysis indicates a day-side temperature of ~8,000 K, and a day-to-night temperature difference of ~6,000 K. The amount of extreme-ultraviolet radiation (with wavelengths 100–912 Å) received by WD 0032–317B is equivalent to that received by planets orbiting close to stars as hot as late B-type stars, and about 5,600 times higher than that of KELT-9b. With a mass of ~75–88 Jupiter masses, this near-hydrogen-burning-limit object is potentially one of the most massive brown dwarfs known.

Original language	English
Pages (from-to)	1329-1340
Number of pages	12
Journal	Nature Astronomy
Volume	7
Issue number	11
DOIs	https://doi.org/10.1038/s41550-023-02048-z
State	Published - Nov 2023

Funding

Funders	Funder number
European Union’s FP7
Agència de Gestió d'Ajuts Universitaris i de Recerca
Ministério da Ciência, Tecnologia, Inovações e Comunicações
National Aeronautics and Space Administration
European Space Agency
Nederlandse Organisatie voor Wetenschappelijk Onderzoek
Diabetes Patient Advocacy Coalition
Agencia Nacional de Investigación y Desarrollo
California Institute of Technology
Science Mission Directorate
Ministerio de Ciencia, Tecnología e Innovación
Gaia Data Processing and Analysis Consortium
European Research Council
National Research Council Canada
Chinese Diabetes Society
UK Research and Innovation
Korea Astronomy and Space Science Institute
Horizon 2020 Framework Programme	833031, 101020057
National Science Foundation	AST-1909022
Science and Technology Facilities Council	ST/T000406/1, ST/S000623/1
Ministerio de Economía y Competitividad	PID2020-117252GB-I00
Generalitat de Catalunya	SGR-386/2021
ESO Science Archive Facility	TAU2021B-004
Istituto Nazionale di Astrofisica	0103.D-0731, 105.20NQ.001
Ministerio de Ciencia e Innovación	PID2020-112949GB-I00

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10.1038/s41550-023-02048-z

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title = "An irradiated-Jupiter analogue hotter than the Sun",

abstract = "Planets orbiting close to hot stars experience intense extreme-ultraviolet radiation, potentially leading to atmosphere evaporation and to thermal dissociation of molecules. However, this extreme regime remains mainly unexplored due to observational challenges. Only a single known ultra-hot giant planet, KELT-9b, receives enough ultraviolet radiation for molecular dissociation, with a day-side temperature of ~4,600 K. An alternative approach uses irradiated brown dwarfs as hot-Jupiter analogues. With atmospheres and radii similar to those of giant planets, brown dwarfs orbiting close to hot Earth-sized white dwarf stars can be directly detected above the glare of the star. Here we report observations revealing an extremely irradiated low-mass companion to the hot white dwarf WD 0032–317. Our analysis indicates a day-side temperature of ~8,000 K, and a day-to-night temperature difference of ~6,000 K. The amount of extreme-ultraviolet radiation (with wavelengths 100–912 {\AA}) received by WD 0032–317B is equivalent to that received by planets orbiting close to stars as hot as late B-type stars, and about 5,600 times higher than that of KELT-9b. With a mass of ~75–88 Jupiter masses, this near-hydrogen-burning-limit object is potentially one of the most massive brown dwarfs known.",

author = "Na{\textquoteright}ama Hallakoun and Dan Maoz and Istrate, {Alina G.} and Carles Badenes and Elm{\'e} Breedt and G{\"a}nsicke, {Boris T.} and Jha, {Saurabh W.} and Bruno Leibundgut and Filippo Mannucci and Marsh, {Thomas R.} and Gijs Nelemans and Ferdinando Patat and Alberto Rebassa-Mansergas",

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doi = "10.1038/s41550-023-02048-z",

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AU - Hallakoun, Na’ama

AU - Maoz, Dan

AU - Istrate, Alina G.

AU - Badenes, Carles

AU - Breedt, Elmé

AU - Gänsicke, Boris T.

AU - Jha, Saurabh W.

AU - Leibundgut, Bruno

AU - Mannucci, Filippo

AU - Marsh, Thomas R.

AU - Nelemans, Gijs

AU - Patat, Ferdinando

AU - Rebassa-Mansergas, Alberto

PY - 2023/11

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AB - Planets orbiting close to hot stars experience intense extreme-ultraviolet radiation, potentially leading to atmosphere evaporation and to thermal dissociation of molecules. However, this extreme regime remains mainly unexplored due to observational challenges. Only a single known ultra-hot giant planet, KELT-9b, receives enough ultraviolet radiation for molecular dissociation, with a day-side temperature of ~4,600 K. An alternative approach uses irradiated brown dwarfs as hot-Jupiter analogues. With atmospheres and radii similar to those of giant planets, brown dwarfs orbiting close to hot Earth-sized white dwarf stars can be directly detected above the glare of the star. Here we report observations revealing an extremely irradiated low-mass companion to the hot white dwarf WD 0032–317. Our analysis indicates a day-side temperature of ~8,000 K, and a day-to-night temperature difference of ~6,000 K. The amount of extreme-ultraviolet radiation (with wavelengths 100–912 Å) received by WD 0032–317B is equivalent to that received by planets orbiting close to stars as hot as late B-type stars, and about 5,600 times higher than that of KELT-9b. With a mass of ~75–88 Jupiter masses, this near-hydrogen-burning-limit object is potentially one of the most massive brown dwarfs known.

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An irradiated-Jupiter analogue hotter than the Sun

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