第24太阳活动周LARES和Ajisai高度大气密度探测

IF 0.7 4区工程技术 Q4 ENGINEERING, AEROSPACE

Transactions of the Japan Society for Aeronautical and Space Sciences Pub Date : 2021-01-01 DOI:10.2322/TJSASS.64.125

C. Padrini, L. Anselmo, D. Lucchesi, R. Peron, M. Bassan, C. Magnafico, G. Pucacco, M. Visco

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引用次数: 0

摘要

在第24个太阳活动周期，放置在平均测地高度在1450 ~ 1500 km之间的近圆形轨道上的被动球形卫星LARES和Ajisai被用作探测中性大气密度和6种热层模式在主要原子种类被氢和氦所争夺的轨道状态下的性能的有力工具，而精确的卫星测量是稀缺的。分析的出发点是精确确定卫星中心轨道系统的长期半长轴衰减率和相应的中性阻力加速度。然后，对于每颗卫星、热层模型和太阳活动水平，找到了能够再现观测到的轨道衰减的阻力系数。最后将这些系数与为两颗卫星计算的物理阻力系数进行比较，以评估影响热层密度模型的偏差。他们中没有一个人可以无条件地被认为是最好的;具体结果取决于太阳活动和卫星穿过的大气区域。在太阳活动极大期，检测到与卫星轨道倾角有关的额外密度偏差。

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Sounding the Atmospheric Density at the Altitude of LARES and Ajisai during Solar Cycle 24

During Solar Cycle 24, the passive spherical satellites LARES and Ajisai, placed in nearly circular orbits with mean geodetic altitudes between 1450 and 1500 km, were used as powerful tools to probe the neutral atmosphere density and the performances of six thermospheric models in orbital regimes for which the role of dominant atomic species is contended by hydrogen and helium, and accurate satellite measurements are scarce. The starting point of the analysis was the accurate determination of the secular semi-major axis decay rate and the corresponding neutral drag acceleration in a satellite- centered orbital system. Then, for each satellite, thermospheric model and solar activity level, the drag coefficients capable of reproducing the orbital decay observed were found. These coefficients were finally compared with the physical drag coefficients computed for both satellites in order to assess the biases affecting the thermospheric density models. None of them could be considered unconditionally the best; the specific outcome depending on solar activity and the regions of the atmosphere crossed by the satellites. During solar maximum conditions, an additional density bias linked to the satellite orbit inclination was detected.

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