ABSTRACT: We examined the role of turbulence on the evolution of the spatial structure of a thin phytoplankton layer. The approach used the small autonomous underwater vehicle (AUV), T-REMUS (turbulence-remote environmental measuring units), which is equipped with optical and physical micro- and fine-scale sensors. As part of the Layered Organization in the Coastal Ocean (LOCO) experiment, T-REMUS was deployed in a very shallow region of Monterey Bay, California, USA, over an 8 h nighttime period in summer 2006. A thin layer of chlorophyll a (chl a) was observed throughout the entire experimental period. The center of the thin layer deepened with time, crossed isotherms, and then settled into a strong turbulence layer. This result is in sharp contrast to previous conclusions that biological thin layers only occur in regions of weak turbulence. Our observations indicated that the turbulence field itself was constrained to be in a thin layer by the surrounding strong density stratification. The chl a material, acting as a passive Lagrangian tracer, became embedded within the turbulent field. With time, both the turbulent field and the embedded chl a thin layer were observed to collapse vertically.
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机译:摘要:我们研究了湍流对浮游植物薄层空间结构演变的作用。该方法使用了小型自主水下航行器(AUV)T-REMUS(湍流远程环境测量装置),该装置配备了光学和物理微型和精细传感器。作为沿海海洋分层组织(LOCO)实验的一部分,T-REMUS在2006年夏季的8小时夜间时间内部署在美国加利福尼亚州蒙特利湾的一个非常浅的地区。一薄层叶绿素 a (chl a )。薄层的中心随时间加深,等温线交叉,然后沉降为一个强湍流层。该结果与以前的结论形成鲜明对比,以前的结论是生物薄层仅出现在湍流较弱的区域。我们的观察表明,湍流场本身被周围的强密度分层约束为薄层。用作被动拉格朗日示踪剂的chl a 材料被嵌入到湍流场中。随着时间的流逝,湍流场和嵌入的chl a 薄层均会垂直塌陷。
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