Space-Based Sentinels for Measurement of Infrared Cooling in the Thermosphere for Space Weather Nowcasting and Forecasting.

IF 3.8 2区 地球科学 Q2 ASTRONOMY & ASTROPHYSICS Space Weather-The International Journal of Research and Applications Pub Date : 2018-04-01 DOI:10.1002/2017SW001757
Martin G Mlynczak, Delores J Knipp, Linda A Hunt, John Gaebler, Tomoko Matsuo, Liam M Kilcommons, Cindy L Young
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引用次数: 18

Abstract

Infrared radiative cooling by nitric oxide (NO) and carbon dioxide (CO2) modulates the thermosphere's density and thermal response to geomagnetic storms. Satellite tracking and collision avoidance planning require accurate density forecasts during these events. Over the past several years, failed density forecasts have been tied to the onset of rapid and significant cooling due to production of NO and its associated radiative cooling via emission of infrared radiation at 5.3 μm. These results have been diagnosed, after the fact, through analyses of measurements of infrared cooling made by the Sounding of the Atmosphere using Broadband Emission Radiometry instrument now in orbit over 16 years on the National Aeronautics and Space Administration Thermosphere, Ionosphere, Mesosphere Energetics and Dynamics satellite. Radiative cooling rates for NO and CO2 have been further shown to be directly correlated with composition and exospheric temperature changes during geomagnetic storms. These results strongly suggest that a network of smallsats observing the infrared radiative cooling of the thermosphere could serve as space weather sentinels. These sentinels would observe and provide radiative cooling rate data in real time to generate nowcasts of density and aerodynamic drag on space vehicles. Currently, radiative cooling is not directly considered in operational space weather forecast models. In addition, recent research has shown that different geomagnetic storm types generate substantially different infrared radiative response, and hence, substantially different thermospheric density response. The ability to identify these storms, and to measure and predict the Earth's response to them, should enable substantial improvement in thermospheric density forecasts.

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用于测量热层红外冷却的天基哨兵,用于空间天气预报和预报。
一氧化氮(NO)和二氧化碳(CO2)的红外辐射冷却调节了热层的密度和对地磁风暴的热响应。卫星跟踪和防撞规划需要在这些事件期间进行准确的密度预测。在过去的几年里,失败的密度预测与NO的产生及其通过5.3μm红外辐射的相关辐射冷却导致的快速显著冷却的开始有关。这些结果是在事后通过分析利用美国国家航空航天局热球、电离层、中圈能量学和动力学卫星上的宽带发射辐射测量仪探测大气层所进行的红外冷却测量而得到诊断的。NO和CO2的辐射冷却速率已被进一步证明与地磁风暴期间的成分和外层温度变化直接相关。这些结果有力地表明,观测热层红外辐射冷却的小型卫星网络可以作为空间天气哨兵。这些哨兵将实时观测并提供辐射冷却率数据,以生成航天器密度和空气动力学阻力的实时预报。目前,在运行的空间天气预报模型中没有直接考虑辐射冷却。此外,最近的研究表明,不同的地磁暴类型产生了显著不同的红外辐射响应,因此产生了明显不同的热层密度响应。能够识别这些风暴,并测量和预测地球对它们的反应,应该能够大大改进热层密度预测。
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来源期刊
CiteScore
5.90
自引率
29.70%
发文量
166
审稿时长
>12 weeks
期刊介绍: Space Weather: The International Journal of Research and Applications (SWE) is devoted to understanding and forecasting space weather. The scope of understanding and forecasting includes: origins, propagation and interactions of solar-produced processes within geospace; interactions in Earth’s space-atmosphere interface region produced by disturbances from above and below; influences of cosmic rays on humans, hardware, and signals; and comparisons of these types of interactions and influences with the atmospheres of neighboring planets and Earth’s moon. Manuscripts should emphasize impacts on technical systems including telecommunications, transportation, electric power, satellite navigation, avionics/spacecraft design and operations, human spaceflight, and other systems. Manuscripts that describe models or space environment climatology should clearly state how the results can be applied.
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