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西南大西洋热带海域环境条件与声散射层的精细垂直关系。

Fine-scale vertical relationships between environmental conditions and sound scattering layers in the Southwestern Tropical Atlantic.

机构信息

Laboratório de Oceanografia Física Estuarina e Costeira, Departamento de Oceanografia, UFPE, Recife, Pernambuco, Brazil.

LEMAR, UBO, IFREMER, IRD, CNRS, Technopole Brest Iroise, Plouzané, France.

出版信息

PLoS One. 2023 Aug 4;18(8):e0284953. doi: 10.1371/journal.pone.0284953. eCollection 2023.

DOI:10.1371/journal.pone.0284953
PMID:37540685
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10403096/
Abstract

Ocean dynamics initiate the structure of nutrient income driving primary producers, and these, in turn, shape the distribution of subsequent trophic levels until the whole pelagic community reflects the physicochemical structure of the ocean. Despite the importance of bottom-up structuring in pelagic ecosystems, fine-scale studies of biophysical interactions along depth are scarce and challenging. To improve our understanding of such relationships, we analyzed the vertical structure of key oceanographic variables along with the distribution of acoustic biomass from multi-frequency acoustic data (38, 70, and 120 kHz) as a reference for pelagic fauna. In addition, we took advantage of species distribution databases collected at the same time to provide further interpretation. The study was performed in the Southwestern Tropical Atlantic of northeast Brazil in spring 2015 and autumn 2017, periods representative of canonical spring and autumn conditions in terms of thermohaline structure and current dynamics. We show that chlorophyll-a, oxygen, current, and stratification are important drivers for the distribution of sound scattering biota but that their relative importance depends on the area, the depth range, and the diel cycle. Prominent sound scattering layers (SSLs) in the epipelagic layer were associated with strong stratification and subsurface chlorophyll-a maximum. In areas where chlorophyll-a maxima were deeper than the peak of stratifications, SSLs were more correlated with stratification than subsurface chlorophyll maxima. Dissolved oxygen seems to be a driver in locations where lower oxygen concentration occurs in the subsurface. Finally, our results suggest that organisms seem to avoid strong currents core. However, future works are needed to better understand the role of currents on the vertical distribution of organisms.

摘要

海洋动力启动了营养物质输入的结构,驱动初级生产者,而这些生产者又反过来塑造了后续营养层次的分布,直到整个浮游生物群落反映出海洋的物理化学结构。尽管在浮游生态系统中,自下而上的结构很重要,但沿深度进行的生物物理相互作用的精细研究仍然很少且具有挑战性。为了提高我们对这些关系的理解,我们分析了关键海洋变量的垂直结构以及多频声学数据(38、70 和 120 kHz)的声学生物量分布,作为浮游动物的参考。此外,我们还利用同时收集的物种分布数据库进行了进一步的解释。该研究于 2015 年春季和 2017 年秋季在巴西东北部的西南热带大西洋进行,这两个时期在温盐结构和海流动力学方面代表了典型的春、秋条件。我们表明,叶绿素-a、氧气、海流和分层是声音散射生物分布的重要驱动因素,但它们的相对重要性取决于区域、深度范围和昼夜周期。在真光层中出现的明显声音散射层(SSL)与强烈的分层和次表层叶绿素最大值有关。在叶绿素最大值比分层峰值更深的区域,SSL 与分层的相关性比与次表层叶绿素最大值的相关性更强。溶解氧似乎是在次表层出现较低氧浓度的地方的驱动因素。最后,我们的结果表明,生物似乎避免在强海流核心区域出现。然而,需要进一步的研究来更好地理解海流对生物垂直分布的作用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9c89/10403096/ab65ba2844cf/pone.0284953.g009.jpg
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