The atmosphere of Titan in late northern summer from JWST and Keck observations

IF 12.9 1区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Nature Astronomy Pub Date : 2025-05-14 DOI:10.1038/s41550-025-02537-3

Conor A. Nixon, Bruno Bézard, Thomas Cornet, Brandon Park Coy, Imke de Pater, Maël Es-Sayeh, Heidi B. Hammel, Emmanuel Lellouch, Nicholas A. Lombardo, Manuel López-Puertas, Juan M. Lora, Pascal Rannou, Sébastien Rodriguez, Nicholas A. Teanby, Elizabeth P. Turtle, Richard K. Achterberg, Carlos Alvarez, Ashley G. Davies, Katherine de Kleer, Greg Doppmann, Leigh N. Fletcher, Alexander G. Hayes, Bryan J. Holler, Patrick G. J. Irwin, Carolyn Jordan, Oliver R. T. King, Nicholas W. Kutsop, Theresa C. Marlin, Henrik Melin, Stefanie N. Milam, Edward M. Molter, Luke Moore, Yaniss Nyffenegger-Péré, James O’Donoghue, John O’Meara, Scot C. R. Rafkin, Michael T. Roman, Arina Rostopchina, Naomi Rowe-Gurney, Carl Schmidt, Judy Schmidt, Christophe Sotin, Tom S. Stallard, John A. Stansberry, Robert A. West

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Abstract

Saturn’s moon Titan undergoes a long annual cycle of 29.45 Earth years. Titan’s northern winter and spring were investigated in detail by the Cassini–Huygens spacecraft (2004–2017), but the northern summer season remains sparsely studied. Here we present new observations from the James Webb Space Telescope (JWST) and Keck II telescope made in 2022 and 2023 during Titan’s late northern summer. Using JWST’s mid-infrared instrument, we spectroscopically detected the methyl radical, the primary product of methane break-up and key to the formation of ethane and heavier molecules. Using the near-infrared spectrograph onboard JWST, we detected several non-local thermodynamic equilibrium CO and CO₂ emission bands, which allowed us to measure these species over a wide altitude range. Lastly, using the near-infrared camera onboard JWST and Keck II, we imaged northern hemisphere tropospheric clouds evolving in altitude, which provided new insights and constraints on seasonal convection patterns. These observations pave the way for new observations and modelling of Titan’s climate and meteorology as it progresses through the northern fall equinox, when its atmosphere is expected to show notable seasonal changes.

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来自JWST和Keck观测的北半球夏末土卫六的大气

土星的卫星土卫六经历了29.45个地球年的漫长周期。卡西尼-惠更斯号航天器（2004-2017）对土卫六北部的冬季和春季进行了详细调查，但对北部夏季的研究仍然很少。在这里，我们展示了詹姆斯韦伯太空望远镜（JWST）和凯克II望远镜在2022年和2023年土卫六北部夏末所做的新观测。利用JWST的中红外仪器，我们对甲基自由基进行了光谱检测，甲基自由基是甲烷裂解的主要产物，也是乙烷和更重分子形成的关键。利用JWST上的近红外光谱仪，我们检测到几个非局部热力学平衡的CO和CO2排放波段，这使我们能够在很宽的海拔范围内测量这些物种。最后，利用JWST和Keck II上的近红外相机，我们对北半球对流层云在高度上的演变进行了成像，为季节性对流模式提供了新的见解和约束。这些观测为土卫六在北方秋分时的气候和气象的新观测和建模铺平了道路，届时土卫六的大气预计会出现显著的季节性变化。

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来源期刊

Nature Astronomy Physics and Astronomy-Astronomy and Astrophysics

CiteScore

19.50

自引率

2.80%

发文量

252

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