Abstract
Falling-sphere sounding remains an important method for in situ determination in the middle atmosphere and is the only determination method within the altitude range of 60–100 km. Traditional single-falling-sphere sounding indicates only the atmospheric density and horizontal wind but not the vertical wind; the fundamental reason is that the equation set for retrieving atmospheric parameters is underdetermined. For tractability, previous studies assumed the vertical wind, which is much smaller than the horizontal wind, to be small or zero. Obtaining vertical wind profiles necessitates making the equations positive definite or overdetermined. An overdetermined equation set consisting of six equations, by which the optimal solution of density and three-dimensional wind can be obtained, can be established by the double-falling-sphere method. Hence, a simulation experiment is designed to retrieve the atmospheric density and three-dimensional wind field by double falling spheres. In the inversion results of the simulation experiment, the retrieved density is consistent with the constructed atmospheric density in magnitude; the density deviation rate does not generally exceed 20% (less than 5% below 60 km). The atmospheric density retrieved by the double-falling-sphere method is more accurate at low altitudes than the single-falling-sphere method. The vertical wind below 50 km and horizontal wind retrieved by double-falling-sphere method is highly consistent with the constructed average wind field. Additionally, the wind field deviation formula is deduced. These results establish the fact that the double-falling-sphere method is effective in detecting atmospheric density and three-dimensional wind.
Highlights
The middle atmosphere, which refers to the region extending from more than 10 km to approximately 100 km above the ground, includes the stratosphere, the mesosphere and the lower thermosphere [1,2]
The deviation of the retrieved atmospheric density increases with decreasing altitude, but the deviation rate of density was generally not more than 20%, especially at altitudes below
A simulation experiment is designed to verify the feasibility of retrieving the atmospheric density and three-dimensional wind field by the double-falling-sphere method
Summary
The middle atmosphere, which refers to the region extending from more than 10 km to approximately 100 km above the ground, includes the stratosphere, the mesosphere and the lower thermosphere [1,2]. Numerous studies of this thin and neutral atmosphere have been carried out [3]. He et al [4] explored the spectral characteristics of temperature fluctuations and three-dimensional wind field fluctuations by a set of near-space high-resolution balloon data and increased the height range of spectral analysis to 38 km. He et al [5] analyzed the scale interactions between the small-scale gravity wave and turbulence in the middle stratosphere. The neutral wind field plays an important role in the energy transmission and atmospheric dynamics and has a great
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
