日本地球惑星科学連合2019年大会

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[J] 口頭発表

セッション記号 A (大気水圏科学) » A-OS 海洋科学・海洋環境

[A-OS14] 沿岸域における混合,渦,内部波に関わる諸現象

2019年5月29日(水) 13:45 〜 15:15 301A (3F)

コンビーナ:増永 英治(Ibaraki University)、永井 平(東京大学理学系研究科)、堤 英輔(東京大学大気海洋研究所)、座長:増永 英治堤 英輔

15:00 〜 15:15

[AOS14-06] 成層が発達する浅水湖における混合と傾圧構造に関する研究

*増永 英治1浅岡 大輝1小室 俊輔2松本 俊一2小野 正人3番場 泰彰3 (1.茨城大学、2.茨城県霞ヶ浦環境科学センター、3.国土交通省)

キーワード:混合、貧酸素水塊、内部波

This study presents mixing and baroclinic structure associated with hypoxia in a shallow lake, Lake Kasumigaura, using field observations and numerical simulations. Hypoxia in stratified lakes is one of the pressing issues for maintaining water environment and ecosystems. Mooring observations show that hypoxia events occur when the stratification is enhanced by the surface heat flux. The stratification (N2) is controlled by the ratio between the surface wind stress and surface heat (buoyanvy) flux. The strength of the stratification/mixing can be simply explained by the Monin-Obukov length scale, LMO. N2 is linearly related with LMO in a log scale with a correlation coefficient of approximately 0.7. According to the heat budget analysis, the bottom sediment heat flux toward the bottom significantly contribute to the heat content as well as the surface heat flux. The heat flux toward the bottom is roughly an order of 100 W m-2 during the summer season, which suppresses mixing near the bottom. The internal wave-like baroclinic structure was observed by high resolution survey using the YODA Profiler. Baroclinic motions are enhanced by the surface wind stress, and they transport the hypoxic water, suspended sediments and phytoplanktons. In addition to field surveys, three-dimensional simulations were conducted with SUNTANS to further investigate physical processes in the lake. Numerical results well agree to observational results and show that baroclinic motions influence in the whole of the lake basin. The wind-induced baroclinic energy is generated in the middle of the lake basin and propagate to the onshore. This study suggests that mixing and baroclinic motions due to buoyancy and wind effects play an important role in the oxygen distribution in Lake Kasumigaura.