Resolving the tidal weather of the thermosphere using GDC

IF 2.6 3区物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS

Frontiers in Astronomy and Space Sciences Pub Date : 2023-09-29 DOI:10.3389/fspas.2023.1282261

Jens Oberheide, Stone M. Gardner, Mukta Neogi

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引用次数: 0

Abstract

NASA’s Geospace Dynamics Constellation (GDC) mission is a six satellite constellation to make in situ measurements of important ionospheric and thermospheric variables to better understand the processes that govern Earth’s near space environment. Scheduled for a 2029 launch into high inclination orbits ∼82° at ∼380 km, the satellite orbit planes will separate over time to provide almost continuous local solar time coverage every day towards the end of the 3 year baseline GDC mission. As such, the neutral temperature and neutral wind measurements of GDC will likely allow the heliophysics community to make significant progress towards resolving the tidal weather of the thermosphere, that is, day-to-day tidal variability, and how it is driven by meteorological processes near the surface and in situ forcing in the ionosphere-thermosphere system. To assess the GDC ability to accurately resolve the tides each day and when in the mission this can be achieved, we conduct an Observational Simulation System Experiment (OSSE) using SD-WACCM-X and the predicted GDC orbits. Our results show that GDC can provide closure on the tidal variability (mean, diurnal and semidiurnal, migrating and nonmigrating) at orbit height in mission phase 4 and throughout most parts of mission phase 3. We also perform Hough Mode Extension fitting of relevant tidal components to study possible connections between the GDC observations and the tides at 200 km, to assess synergies between GDC and the forthcoming DYNAMIC mission (scheduled to be co-launched with GDC) that will measure altitude-resolved winds and temperatures in the ∼100–200 km height range.

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利用GDC解析热层潮汐天气

美国宇航局的地球空间动力学星座(GDC)任务是一个由6颗卫星组成的星座，用于对重要的电离层和热层变量进行现场测量，以更好地了解控制地球近空间环境的过程。计划于2029年发射到高倾角轨道(~ 82°，~ 380公里)，卫星轨道平面将随着时间的推移分离，在3年基线GDC任务结束时几乎每天提供连续的当地太阳时间覆盖。因此，GDC的中性温度和中性风测量可能会使太阳物理学界在解决热层潮汐天气方面取得重大进展，即每日潮汐变化，以及它是如何由近地表的气象过程和电离层-热层系统的原位强迫驱动的。为了评估GDC每天准确解析潮汐的能力以及在任务中何时可以实现这一目标，我们使用SD-WACCM-X和预测的GDC轨道进行了观测模拟系统实验(OSSE)。结果表明，GDC可以提供任务4阶段和任务3阶段大部分时间轨道高度的潮汐变化(平均、日、半日、迁移和非迁移)。我们还对相关潮汐分量进行了霍夫模态扩展拟合，以研究GDC观测与200公里潮汐之间的可能联系，以评估GDC与即将到来的DYNAMIC任务(计划与GDC共同发射)之间的协同作用，后者将测量100-200公里高度范围内的高度分辨风和温度。

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

Frontiers in Astronomy and Space Sciences ASTRONOMY & ASTROPHYSICS-

CiteScore

3.40

自引率

13.30%

发文量

363

审稿时长

14 weeks