Spatial Variations of Jovian Tropospheric Ammonia via Ground-Based Imaging

IF 2.9 3区 地球科学 Q2 ASTRONOMY & ASTROPHYSICS
S. M. Hill, P. G. J. Irwin, C. Alexander, J. H. Rogers
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Abstract

Current understanding of the ammonia distribution in Jupiter's atmosphere is provided by observations from major ground-based facilities and spacecraft, and analyzed with sophisticated retrieval models that recover high fidelity information, but are limited in spatial and temporal coverage. Here we show that the ammonia abundance in Jupiter's upper troposphere, which tracks the overturning atmospheric circulation, can be simply, but reliably determined from continuum-divided ammonia and methane absorption-band images made with a moderate-sized Schmidt-Cassegrain telescope (SCT). In 2020–2021, Jupiter was imaged in the 647-nm ammonia absorption band and adjacent continuum bands with a 0.28-m SCT, demonstrating that the spatially resolved ammonia optical depth could be determined with such a telescope. In 2022–2023, a 619 nm methane-band filter was added to provide a constant reference against which to correct the ammonia abundances (column-averaged mole fraction) for cloud opacity variations. These 0.28-m SCT results are compared with observations from: (a) the MUSE instrument on ESO's Very Large Telescope (b) the TEXES mid-infrared spectrometer used on NASA's InfraRed Telescope Facility; and (c) the Gemini telescopes, and are shown to provide reliable maps of ammonia abundance. Meridional and longitudinal features are examined, including the Equatorial Zone (EZ) ammonia enhancement, the North Equatorial Belt depletion, depletion above the Great Red Spot, and longitudinal enhancements in the northern EZ. This work demonstrates meaningful ammonia monitoring can be achieved with small telescopes that can complement spacecraft and major ground-based facility observations.

Abstract Image

通过地面成像观察木卫二对流层氨的空间变化
目前对木星大气中氨分布情况的了解来自主要地面设施和航天器的观测,并通过复杂的检索模型进行分析,这些模型能够恢复高保真信息,但在空间和时间覆盖范围上受到限制。在这里,我们展示了木星对流层上部的氨丰度,它追踪着翻转的大气环流,可以通过中等大小的施密特-卡塞格伦望远镜(SCT)拍摄的氨和甲烷吸收波段连续分光图像简单而可靠地确定。2020-2021 年,用一台 0.28 米口径的施密特-卡塞格伦望远镜拍摄了木星 647 纳米氨吸收波段和邻近连续波段的图像,证明用这样的望远镜可以确定空间分辨的氨光学深度。2022-2023 年,增加了一个 619 nm 甲烷波段滤光片,以提供一个恒定的参考,根据云的不透明度变化校正氨丰度(柱平均摩尔分数)。这些 0.28 米 SCT 结果与以下观测结果进行了比较:(a) 欧洲南方天文台甚大望远镜上的 MUSE 仪器;(b) 美国国家航空航天局红外望远镜设施上使用的 TEXES 中红外光谱仪;(c) 双子座望远镜,结果表明它们提供了可靠的氨丰度图。研究了经向和纬向特征,包括赤道区(EZ)氨增量、北赤道带耗竭、大红斑上方耗竭以及赤道区北部的纵向增量。这项工作表明,可以利用小型望远镜对氨进行有意义的监测,从而补充航天器和主要地面设施的观测。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Earth and Space Science
Earth and Space Science Earth and Planetary Sciences-General Earth and Planetary Sciences
CiteScore
5.50
自引率
3.20%
发文量
285
审稿时长
19 weeks
期刊介绍: Marking AGU’s second new open access journal in the last 12 months, Earth and Space Science is the only journal that reflects the expansive range of science represented by AGU’s 62,000 members, including all of the Earth, planetary, and space sciences, and related fields in environmental science, geoengineering, space engineering, and biogeochemistry.
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