JpGU-AGU Joint Meeting 2020

講演情報

[E] ポスター発表

セッション記号 A (大気水圏科学) » A-CG 大気海洋・環境科学複合領域・一般

[A-CG44] 中緯度大気海洋相互作用

コンビーナ:釜江 陽一(筑波大学生命環境系)、遠山 勝也(気象庁気象研究所)、Hyodae Seo(Woods Hole Oceanographic Institution)、佐々木 克徳(Hokkaido University)

[ACG44-P05] On the maintenance mechanisms for the wintertime subtropical high over the South Indian Ocean

*宮本 歩1中村 尚1宮坂 貴文1,2小坂 優1田口 文明3西井 和晃4 (1.東京大学先端科学技術研究センター、2.気象業務支援センター、3.富山大学都市デザイン学部、4.三重大学大学院生物資源学研究科)

キーワード:亜熱帯高気圧、ストームトラック、南インド洋、アジアモンスーン

Over the South Indian Ocean, the subtropical Mascarene high exhibits a distinct seasonality from the other basins. While the high resides over the eastern portion of the basin in summer, the high resides over the western portion of the basin and its strength as a planetary-wave component is maximized in winter. The present study investigates the maintenance mechanisms for the wintertime subtropical high by using an atmospheric dynamical model and an atmospheric general circulation model.

We find that enhanced storm-track activity maintained by the Agulhas sea surface temperature (SST) front is important for the maintenance of the poleward portion of the subtropical high through the convergences of eddy heat and vorticity fluxes and the resultant acceleration of the climatological-mean westerlies on the poleward side of the high, as shown by the dynamical model experiments. The atmospheric general circulation model experiments further indicate that the Agulhas SST front acts to reinforce the high by energizing the storm-track activity.

The dynamical model experiments also reveal the remote influence from the tropics, especially the Asian summer monsoon region. The enhanced deep convection over the Asian summer monsoon region as well as the equatorial eastern Indian Ocean and western Pacific acts not only to shift the subtropical high westward but also to enhance mid-tropospheric subsidence and equatorward surface winds over the central and western portions of the subtropical South Indian Ocean. The induced subsidence acts to stabilize and dry the free troposphere, and the equatorward surface winds yield near-surface cold advection, both of which are favorable for the low-level cloud formation but unfavorable for the development of deep precipitating clouds. The resultant enhanced radiative cooling and reduced deep condensation heating can reinforce the equatorward portion of the subtropical high.