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Numerical simulation for dispersion of anthropogenic material near shellfish growing area in Geoje Bay
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 Title & Authors
Numerical simulation for dispersion of anthropogenic material near shellfish growing area in Geoje Bay
KIM, Jin-Ho; LEE, Won-Chan; HONG, Sok-Jin; KIM, Dong-Myung; CHANG, Yong-Hyun; JUNG, Woo-Sung;
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Hydrodynamic condition can be used to predict particle movement within water column and the results used to optimize environmental conditions for effective site selection, setting of environmental quality standard, waste dispersion, and pathogen transfer. To predict the extent of movement of particle from land, 3D hydrodynamic model that includes particle tracking module was applied to Geoje Bay and to calibrate particle tracking model, floating buoy measurement is operated. The model results show that short time is required for particles released into system from river to be transported to the shellfish farming area. It takes about 2 days for the particles to shellfish farming area under mean flow condition. It meant Geoje Bay, especially shellfish farming area is vulnerable to anthropogenic waste from river.
Anthropogenic material;Geoje Bay;EFDC;Particle tracking model;Floating Buoy;
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입자추적모델을 이용한 마산만 북부 해역에서의 육상오염물질 확산 수치모의,김진호;정우성;홍석진;이원찬;정용현;김동명;

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