Discovery of H+3 and infrared aurorae at Neptune with JWST

Henrik Melin; Luke Moore; Leigh N. Fletcher; Heidi B. Hammel; James O'Donoghue; Tom S. Stallard; Stephanie N. Milam; Michael Roman; Oliver R.T. King; Naomi Rowe-Gurney; Emma E. Thomas; Ruoyan Wang; Paola I. Tiranti; Jake Harkett; Katie L. Knowles

doi:10.1038/s41550-025-02507-9

Discovery of H+3 and infrared aurorae at Neptune with JWST

Henrik Melin^*, Luke Moore, Leigh N. Fletcher, Heidi B. Hammel, James O'Donoghue, Tom S. Stallard, Stephanie N. Milam, Michael Roman, Oliver R.T. King, Naomi Rowe-Gurney, Emma E. Thomas, Ruoyan Wang, Paola I. Tiranti, Jake Harkett, Katie L. Knowles

^*Corresponding author for this work

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

6 Citations (Scopus)

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Abstract

Emissions from the upper-atmospheric molecular ion have been used to study the global-scale interactions of Jupiter, Saturn and Uranus with their surrounding space environments for over 30 years, revealing the processes shaping the aurorae. However, despite repeated attempts, and contrary to models that predict it should be present, this ion has proven elusive at Neptune. Here, using observations from the James Webb Space Telescope, we detect at Neptune, as well as distinct infrared southern auroral emissions. The average upper-atmosphere temperature is a factor of two cooler than those derived 34 years ago by Voyager 2, showing that the energy balance of this region is regulated by physical processes acting on a timescale shorter than both Neptunian seasons (40 yr) and the solar cycle.

Original language	English
Pages (from-to)	666-671
Number of pages	6
Journal	Nature Astronomy
Volume	9
Issue number	5
Early online date	26 Mar 2025
DOIs	https://doi.org/10.1038/s41550-025-02507-9
Publication status	Published - 1 May 2025

Keywords

Aurora
Giant Planets

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s41550-025-02507-9Final published version, 1.84 MBLicence: CC BY

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title = "Discovery of H+3 and infrared aurorae at Neptune with JWST",

abstract = "Emissions from the upper-atmospheric molecular ion have been used to study the global-scale interactions of Jupiter, Saturn and Uranus with their surrounding space environments for over 30 years, revealing the processes shaping the aurorae. However, despite repeated attempts, and contrary to models that predict it should be present, this ion has proven elusive at Neptune. Here, using observations from the James Webb Space Telescope, we detect at Neptune, as well as distinct infrared southern auroral emissions. The average upper-atmosphere temperature is a factor of two cooler than those derived 34 years ago by Voyager 2, showing that the energy balance of this region is regulated by physical processes acting on a timescale shorter than both Neptunian seasons (40 yr) and the solar cycle.",

keywords = "Aurora, Giant Planets",

author = "Henrik Melin and Luke Moore and Fletcher, \{Leigh N.\} and Hammel, \{Heidi B.\} and James O'Donoghue and Stallard, \{Tom S.\} and Milam, \{Stephanie N.\} and Michael Roman and King, \{Oliver R.T.\} and Naomi Rowe-Gurney and Thomas, \{Emma E.\} and Ruoyan Wang and Tiranti, \{Paola I.\} and Jake Harkett and Knowles, \{Katie L.\}",

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doi = "10.1038/s41550-025-02507-9",

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AU - Melin, Henrik

AU - Moore, Luke

AU - Fletcher, Leigh N.

AU - Hammel, Heidi B.

AU - O'Donoghue, James

AU - Stallard, Tom S.

AU - Milam, Stephanie N.

AU - Roman, Michael

AU - King, Oliver R.T.

AU - Rowe-Gurney, Naomi

AU - Thomas, Emma E.

AU - Wang, Ruoyan

AU - Tiranti, Paola I.

AU - Harkett, Jake

AU - Knowles, Katie L.

PY - 2025/5/1

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N2 - Emissions from the upper-atmospheric molecular ion have been used to study the global-scale interactions of Jupiter, Saturn and Uranus with their surrounding space environments for over 30 years, revealing the processes shaping the aurorae. However, despite repeated attempts, and contrary to models that predict it should be present, this ion has proven elusive at Neptune. Here, using observations from the James Webb Space Telescope, we detect at Neptune, as well as distinct infrared southern auroral emissions. The average upper-atmosphere temperature is a factor of two cooler than those derived 34 years ago by Voyager 2, showing that the energy balance of this region is regulated by physical processes acting on a timescale shorter than both Neptunian seasons (40 yr) and the solar cycle.

AB - Emissions from the upper-atmospheric molecular ion have been used to study the global-scale interactions of Jupiter, Saturn and Uranus with their surrounding space environments for over 30 years, revealing the processes shaping the aurorae. However, despite repeated attempts, and contrary to models that predict it should be present, this ion has proven elusive at Neptune. Here, using observations from the James Webb Space Telescope, we detect at Neptune, as well as distinct infrared southern auroral emissions. The average upper-atmosphere temperature is a factor of two cooler than those derived 34 years ago by Voyager 2, showing that the energy balance of this region is regulated by physical processes acting on a timescale shorter than both Neptunian seasons (40 yr) and the solar cycle.

KW - Aurora

KW - Giant Planets

UR - https://www.scopus.com/pages/publications/105001499962

U2 - 10.1038/s41550-025-02507-9

DO - 10.1038/s41550-025-02507-9

M3 - Article

C2 - 40417327

SN - 2397-3366

VL - 9

SP - 666

EP - 671

JO - Nature Astronomy

JF - Nature Astronomy

IS - 5

ER -

Discovery of H+3 and infrared aurorae at Neptune with JWST

Abstract

Keywords

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