Dynamic infrared aurora on Jupiter

J. D. Nichols; O. R. T. King; J. T. Clarke; I. de Pater; L. N. Fletcher; H. Melin; L. Moore; C. Tao; T. K. Yeoman

doi:10.1038/s41467-025-58984-z

Dynamic infrared aurora on Jupiter

J. D. Nichols^*, O. R. T. King, J. T. Clarke, I. de Pater, L. N. Fletcher, H. Melin, L. Moore, C. Tao, T. K. Yeoman

^*Corresponding author for this work

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

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Abstract

Auroral emissions are an important diagnostic for a planet’s magnetosphere and upper atmosphere. At the outer planets, the characteristics of emission from the triatomic hydrogen ion H3+ are key to understanding the auroral energy budget. We present James Webb Space Telescope observations of Jupiter’s infrared auroral H3+ emission, exhibiting variability on timescales down to seconds. Together with simultaneous Hubble Space Telescope ultraviolet observations, these results imply an auroral H3+ lifetime of 150 s, and that H3+ cannot efficiently radiate heat deposited by bursty auroral precipitation. However, H3+ radiation is particularly efficient in a dusk active region, which has no significant ultraviolet counterpart. The cause of such emission is unclear. We also present observations of rapid eastward-travelling auroral pulses in the dawn side auroral region and pulsations that propagate rapidly along the Io footprint tail. Together, these observations open a diagnostic window for the jovian magnetosphere and ionosphere.

Original language	English
Article number	3907
Pages (from-to)	1-12
Number of pages	12
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-58984-z
Publication status	Published - 12 May 2025

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title = "Dynamic infrared aurora on Jupiter",

abstract = "Auroral emissions are an important diagnostic for a planet{\textquoteright}s magnetosphere and upper atmosphere. At the outer planets, the characteristics of emission from the triatomic hydrogen ion H3+ are key to understanding the auroral energy budget. We present James Webb Space Telescope observations of Jupiter{\textquoteright}s infrared auroral H3+ emission, exhibiting variability on timescales down to seconds. Together with simultaneous Hubble Space Telescope ultraviolet observations, these results imply an auroral H3+ lifetime of 150 s, and that H3+ cannot efficiently radiate heat deposited by bursty auroral precipitation. However, H3+ radiation is particularly efficient in a dusk active region, which has no significant ultraviolet counterpart. The cause of such emission is unclear. We also present observations of rapid eastward-travelling auroral pulses in the dawn side auroral region and pulsations that propagate rapidly along the Io footprint tail. Together, these observations open a diagnostic window for the jovian magnetosphere and ionosphere.",

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AU - Nichols, J. D.

AU - King, O. R. T.

AU - Clarke, J. T.

AU - de Pater, I.

AU - Fletcher, L. N.

AU - Melin, H.

AU - Moore, L.

AU - Tao, C.

AU - Yeoman, T. K.

PY - 2025/5/12

Y1 - 2025/5/12

N2 - Auroral emissions are an important diagnostic for a planet’s magnetosphere and upper atmosphere. At the outer planets, the characteristics of emission from the triatomic hydrogen ion H3+ are key to understanding the auroral energy budget. We present James Webb Space Telescope observations of Jupiter’s infrared auroral H3+ emission, exhibiting variability on timescales down to seconds. Together with simultaneous Hubble Space Telescope ultraviolet observations, these results imply an auroral H3+ lifetime of 150 s, and that H3+ cannot efficiently radiate heat deposited by bursty auroral precipitation. However, H3+ radiation is particularly efficient in a dusk active region, which has no significant ultraviolet counterpart. The cause of such emission is unclear. We also present observations of rapid eastward-travelling auroral pulses in the dawn side auroral region and pulsations that propagate rapidly along the Io footprint tail. Together, these observations open a diagnostic window for the jovian magnetosphere and ionosphere.

AB - Auroral emissions are an important diagnostic for a planet’s magnetosphere and upper atmosphere. At the outer planets, the characteristics of emission from the triatomic hydrogen ion H3+ are key to understanding the auroral energy budget. We present James Webb Space Telescope observations of Jupiter’s infrared auroral H3+ emission, exhibiting variability on timescales down to seconds. Together with simultaneous Hubble Space Telescope ultraviolet observations, these results imply an auroral H3+ lifetime of 150 s, and that H3+ cannot efficiently radiate heat deposited by bursty auroral precipitation. However, H3+ radiation is particularly efficient in a dusk active region, which has no significant ultraviolet counterpart. The cause of such emission is unclear. We also present observations of rapid eastward-travelling auroral pulses in the dawn side auroral region and pulsations that propagate rapidly along the Io footprint tail. Together, these observations open a diagnostic window for the jovian magnetosphere and ionosphere.

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Dynamic infrared aurora on Jupiter

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