Stratospheric aerosols and C6H6 in Jupiter's south polar region from JWST/MIRI observations

Pablo Rodríguez-Ovalle; Sandrine Guerlet; Thierry Fouchet; Jake Harkett; Thibault Cavalié; Vincent Hue; Sandrine Vinatier; Manuel López-Puertas; Leigh N. Fletcher; Emmanuel Lellouch; Ricardo Hueso; Imke De Pater; Glenn S. Orton; Michael T. Roman; Heidi B. Hammel; Stefanie N. Milam; Oliver R.T. King

doi:10.1051/0004-6361/202451453

Stratospheric aerosols and C₆H₆ in Jupiter's south polar region from JWST/MIRI observations

Pablo Rodríguez-Ovalle
, Sandrine Guerlet
, Thierry Fouchet
, Jake Harkett
, Thibault Cavalié
, Vincent Hue
, Sandrine Vinatier
, Manuel López-Puertas
, Leigh N. Fletcher
, Emmanuel Lellouch
, Ricardo Hueso
, Imke De Pater
, Glenn S. Orton
, Michael T. Roman
, Heidi B. Hammel
, Stefanie N. Milam
, Oliver R.T. King

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

Abstract

Context. The polar atmosphere of Jupiter is significantly affected by auroral activity, which can induce both thermal and chemical differences compared to the rest of the atmosphere. In particular, auroral activity enhances the production of various hydrocarbons, including benzene. Benzene could be a potential precursor to the formation of the stratospheric hazes. Aims. We investigated the spatial distribution of the benzene abundance across latitudes ranging from 50 S to 81 S and 17 S to 25 S. Additionally, we examined the chemical origin of polar aerosols and their latitudinal distribution. Methods. We employed James Webb Space Telescope (JWST) Mid InfraRed Instrument (MIRI) observations to measure the benzene abundance based on its emission at 674 cm^-1. Additionally, we examined the spectral dependence of the aerosol opacity within the 680-760 and 1380-1500 cm^-1 spectral ranges, and mapped their distribution from 80 S-50 S. Results. At latitudes lower than 60 S, benzene is found to be up to ten times more abundant compared to lower latitudes. This enhancement of C₆H₆ is well mixed longitudinally and not particularly concentrated inside the auroral oval. Photochemical models predict a decrease in the abundance as we approach the mid latitudes, but fail at polar latitudes as they do not include ion-neutral chemistry. Moreover, we find that the southern polar atmosphere is enriched with aerosols at ~10 mbar. The optical depth of the aerosols increases at latitudes poleward of ~60 S, similar to the enhancement of C₆H₆. These aerosols have spectral features similar to the aerosols of Titan and Saturn, and the mass loading is of ~1.2 ± 0.2 A×10^-4 g cm^-2. Finally, we quantified the impact of these aerosols on the retrieved temperature structure, causing a decrease in the temperature at pressure levels deeper than 10 mbar. Conclusions. We find that the auroral precipitation produces abundant stratospheric aerosols, which must play an important role in the chemistry and dynamics of the planet.

Original language	English
Article number	A51
Journal	Astronomy and Astrophysics
Volume	691
DOIs	https://doi.org/10.1051/0004-6361/202451453
Publication status	Published - 1 Nov 2024

Keywords

Planets and satellites: atmospheres
Planets and satellites: aurorae
Planets and satellites: composition
Planets and satellites: gaseous planets

Access to Document

10.1051/0004-6361/202451453

Cite this

Rodríguez-Ovalle, P., Guerlet, S., Fouchet, T., Harkett, J., Cavalié, T., Hue, V., Vinatier, S., López-Puertas, M., Fletcher, L. N., Lellouch, E., Hueso, R., De Pater, I., Orton, G. S., Roman, M. T., Hammel, H. B., Milam, S. N., & King, O. R. T. (2024). Stratospheric aerosols and C₆H₆ in Jupiter's south polar region from JWST/MIRI observations. Astronomy and Astrophysics, 691, Article A51. https://doi.org/10.1051/0004-6361/202451453

@article{d23f7e82d6954c30a67fcdb6e9037543,

title = "Stratospheric aerosols and C6H6 in Jupiter's south polar region from JWST/MIRI observations",

abstract = "Context. The polar atmosphere of Jupiter is significantly affected by auroral activity, which can induce both thermal and chemical differences compared to the rest of the atmosphere. In particular, auroral activity enhances the production of various hydrocarbons, including benzene. Benzene could be a potential precursor to the formation of the stratospheric hazes. Aims. We investigated the spatial distribution of the benzene abundance across latitudes ranging from 50 S to 81 S and 17 S to 25 S. Additionally, we examined the chemical origin of polar aerosols and their latitudinal distribution. Methods. We employed James Webb Space Telescope (JWST) Mid InfraRed Instrument (MIRI) observations to measure the benzene abundance based on its emission at 674 cm-1. Additionally, we examined the spectral dependence of the aerosol opacity within the 680-760 and 1380-1500 cm-1 spectral ranges, and mapped their distribution from 80 S-50 S. Results. At latitudes lower than 60 S, benzene is found to be up to ten times more abundant compared to lower latitudes. This enhancement of C6H6 is well mixed longitudinally and not particularly concentrated inside the auroral oval. Photochemical models predict a decrease in the abundance as we approach the mid latitudes, but fail at polar latitudes as they do not include ion-neutral chemistry. Moreover, we find that the southern polar atmosphere is enriched with aerosols at \textasciitilde{}10 mbar. The optical depth of the aerosols increases at latitudes poleward of \textasciitilde{}60 S, similar to the enhancement of C6H6. These aerosols have spectral features similar to the aerosols of Titan and Saturn, and the mass loading is of \textasciitilde{}1.2 ± 0.2 A×10-4 g cm-2. Finally, we quantified the impact of these aerosols on the retrieved temperature structure, causing a decrease in the temperature at pressure levels deeper than 10 mbar. Conclusions. We find that the auroral precipitation produces abundant stratospheric aerosols, which must play an important role in the chemistry and dynamics of the planet.",

keywords = "Planets and satellites: atmospheres, Planets and satellites: aurorae, Planets and satellites: composition, Planets and satellites: gaseous planets",

author = "Pablo Rodr{\'i}guez-Ovalle and Sandrine Guerlet and Thierry Fouchet and Jake Harkett and Thibault Cavali{\'e} and Vincent Hue and Sandrine Vinatier and Manuel L{\'o}pez-Puertas and Fletcher, \{Leigh N.\} and Emmanuel Lellouch and Ricardo Hueso and \{De Pater\}, Imke and Orton, \{Glenn S.\} and Roman, \{Michael T.\} and Hammel, \{Heidi B.\} and Milam, \{Stefanie N.\} and King, \{Oliver R.T.\}",

note = "Publisher Copyright: {\textcopyright} The Authors 2024.",

year = "2024",

month = nov,

day = "1",

doi = "10.1051/0004-6361/202451453",

language = "English",

volume = "691",

journal = "Astronomy and Astrophysics",

issn = "0004-6361",

}

Rodríguez-Ovalle, P, Guerlet, S, Fouchet, T, Harkett, J, Cavalié, T, Hue, V, Vinatier, S, López-Puertas, M, Fletcher, LN, Lellouch, E, Hueso, R, De Pater, I, Orton, GS, Roman, MT, Hammel, HB, Milam, SN & King, ORT 2024, 'Stratospheric aerosols and C₆H₆ in Jupiter's south polar region from JWST/MIRI observations', Astronomy and Astrophysics, vol. 691, A51. https://doi.org/10.1051/0004-6361/202451453

TY - JOUR

T1 - Stratospheric aerosols and C6H6 in Jupiter's south polar region from JWST/MIRI observations

AU - Rodríguez-Ovalle, Pablo

AU - Guerlet, Sandrine

AU - Fouchet, Thierry

AU - Harkett, Jake

AU - Cavalié, Thibault

AU - Hue, Vincent

AU - Vinatier, Sandrine

AU - López-Puertas, Manuel

AU - Fletcher, Leigh N.

AU - Lellouch, Emmanuel

AU - Hueso, Ricardo

AU - De Pater, Imke

AU - Orton, Glenn S.

AU - Roman, Michael T.

AU - Hammel, Heidi B.

AU - Milam, Stefanie N.

AU - King, Oliver R.T.

PY - 2024/11/1

Y1 - 2024/11/1

N2 - Context. The polar atmosphere of Jupiter is significantly affected by auroral activity, which can induce both thermal and chemical differences compared to the rest of the atmosphere. In particular, auroral activity enhances the production of various hydrocarbons, including benzene. Benzene could be a potential precursor to the formation of the stratospheric hazes. Aims. We investigated the spatial distribution of the benzene abundance across latitudes ranging from 50 S to 81 S and 17 S to 25 S. Additionally, we examined the chemical origin of polar aerosols and their latitudinal distribution. Methods. We employed James Webb Space Telescope (JWST) Mid InfraRed Instrument (MIRI) observations to measure the benzene abundance based on its emission at 674 cm-1. Additionally, we examined the spectral dependence of the aerosol opacity within the 680-760 and 1380-1500 cm-1 spectral ranges, and mapped their distribution from 80 S-50 S. Results. At latitudes lower than 60 S, benzene is found to be up to ten times more abundant compared to lower latitudes. This enhancement of C6H6 is well mixed longitudinally and not particularly concentrated inside the auroral oval. Photochemical models predict a decrease in the abundance as we approach the mid latitudes, but fail at polar latitudes as they do not include ion-neutral chemistry. Moreover, we find that the southern polar atmosphere is enriched with aerosols at ~10 mbar. The optical depth of the aerosols increases at latitudes poleward of ~60 S, similar to the enhancement of C6H6. These aerosols have spectral features similar to the aerosols of Titan and Saturn, and the mass loading is of ~1.2 ± 0.2 A×10-4 g cm-2. Finally, we quantified the impact of these aerosols on the retrieved temperature structure, causing a decrease in the temperature at pressure levels deeper than 10 mbar. Conclusions. We find that the auroral precipitation produces abundant stratospheric aerosols, which must play an important role in the chemistry and dynamics of the planet.

AB - Context. The polar atmosphere of Jupiter is significantly affected by auroral activity, which can induce both thermal and chemical differences compared to the rest of the atmosphere. In particular, auroral activity enhances the production of various hydrocarbons, including benzene. Benzene could be a potential precursor to the formation of the stratospheric hazes. Aims. We investigated the spatial distribution of the benzene abundance across latitudes ranging from 50 S to 81 S and 17 S to 25 S. Additionally, we examined the chemical origin of polar aerosols and their latitudinal distribution. Methods. We employed James Webb Space Telescope (JWST) Mid InfraRed Instrument (MIRI) observations to measure the benzene abundance based on its emission at 674 cm-1. Additionally, we examined the spectral dependence of the aerosol opacity within the 680-760 and 1380-1500 cm-1 spectral ranges, and mapped their distribution from 80 S-50 S. Results. At latitudes lower than 60 S, benzene is found to be up to ten times more abundant compared to lower latitudes. This enhancement of C6H6 is well mixed longitudinally and not particularly concentrated inside the auroral oval. Photochemical models predict a decrease in the abundance as we approach the mid latitudes, but fail at polar latitudes as they do not include ion-neutral chemistry. Moreover, we find that the southern polar atmosphere is enriched with aerosols at ~10 mbar. The optical depth of the aerosols increases at latitudes poleward of ~60 S, similar to the enhancement of C6H6. These aerosols have spectral features similar to the aerosols of Titan and Saturn, and the mass loading is of ~1.2 ± 0.2 A×10-4 g cm-2. Finally, we quantified the impact of these aerosols on the retrieved temperature structure, causing a decrease in the temperature at pressure levels deeper than 10 mbar. Conclusions. We find that the auroral precipitation produces abundant stratospheric aerosols, which must play an important role in the chemistry and dynamics of the planet.

KW - Planets and satellites: atmospheres

KW - Planets and satellites: aurorae

KW - Planets and satellites: composition

KW - Planets and satellites: gaseous planets

U2 - 10.1051/0004-6361/202451453

DO - 10.1051/0004-6361/202451453

M3 - Article

AN - SCOPUS:85208284383

SN - 0004-6361

VL - 691

JO - Astronomy and Astrophysics

JF - Astronomy and Astrophysics

M1 - A51