日本地球惑星科学連合2015年大会

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インターナショナルセッション(口頭発表)

セッション記号 A (大気水圏科学) » A-AS 大気科学・気象学・大気環境

[A-AS01] Advances in Atmospheric Remote Sensing Techniques

2015年5月27日(水) 14:15 〜 16:00 301B (3F)

コンビーナ:*Wenbo Sun(Science Systems and Applications, Inc.)、Yongxiang Hu(NASA Langley Research Center)、Kenji Kai(Nagoya University)、Kazuaki Kawamoto(Graduate School of Fisheries Science and Environmental Studies, Nagasaki University)、座長:Wenbo Sun(Science Systems and Applications, Inc.)、Yongxiang Hu(NASA Langley Research Center)、Kazuaki Kawamoto(Graduate School of Fisheries Science and Environmental Studies, Nagasaki University)

15:15 〜 15:30

[AAS01-03] Atmospheric Gravity Waves: MST Radars and Sondes

*Lakshmi KANTHA1Tyler MIXA1Hiroyuki HASHIGUCHI2Toshitaka TSUDA2Venkat RATNAM3A JAYARAMAN3 (1.University of Colorado, Boulder, USA、2.RISH, Kyoto University, Japan、3.NARL, Gadanki, India)

キーワード:MST radar, Radiosonde, Atmospheric gravity waves

MST radars have proved to be extremely useful in monitoring atmospheric gravity waves and understanding their role in the middle and upper atmosphere dynamics. However, there are only a few such radars around the world, making routine monitoring of gravity waves in the global atmosphere impossible. Using sondes to extract wave information such as the momentum flux would help monitor and study gravity waves in the troposphere and the lower stratosphere, provided the method can be demonstrated to yield realistic results. As a sonde ascends, its vertical velocity is modulated by gravity waves so that, in principle, it should be possible to extract wave properties such as the energy density and momentum flux. However, the aerodynamics of the flow around the balloon complicates the sonde vertical motion. The Reynolds number of the flow is around the transitional value so that transition of the boundary layer on the forward hemisphere from laminar to turbulent can change the wake size and hence the drag in an unpredictable fashion, affecting the vertical velocity. We have modeled the behavior of the balloon assuming it to be elastic so that the sonde vertical velocity can be modeled and the transition from low drag to high drag assessed. The extensive sonde dataset collected during the 2005 CPEA II campaign at the Koto Tabang Equatorial Radar facility has been used to explore the technique. The vertical velocity fluctuations resulting from the model have been used to estimate atmospheric gravity wave properties at the radar site during the month-long campaign.

Proper validation of sonde-extracted gravity wave properties requires comparison with another independent, reliable and simultaneous set of measurements. MST radars, being the gold standard for gravity wave studies, provide such an opportunity. At the NARL MST radar facility in Gadanki, India, there exist radar data obtained during some sonde launches. We have used these data to compare wave properties extracted from sondes with those extracted from radar horizontal and vertical wind velocity measurements. We find the sonde provides results consistent with radar measurements, thus providing more confidence in the utility of the technique for studying gravity waves in the global stratosphere. We will present results of these comparisons and discuss their potential utility and some unresolved issues.