在生物物理界定的省份中模拟小龙鱼的全球特征

IF 3.8 3区 地球科学 Q1 OCEANOGRAPHY
S. Albernhe , T. Gorgues , P. Lehodey , C. Menkes , O. Titaud , S. Magon De La Giclais , A. Conchon
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引用次数: 0

摘要

微小浮游生物是生态系统的中营养级,通过昼夜垂直洄游向深海输出活性碳。根据与环境变量的关系,更好地确定微小浮游生物功能群的特征,有助于管理海洋资源、保护生物多样性和更好地了解气候变化的影响。为此,将全球海洋区域化为同质区域的方法正引起越来越多的关注。然而,已发表的区域划分方法(i) 源自环境作用力,并不特别关注微小浮游生物;(ii) 源自声学反向散射,无法直接估算微小浮游生物的生物量。在此,我们建议填补生物物理区域划分与微浮游生物生物量之间的空白。我们利用已知会影响微小浮游生物的全球环境变量:表层温度、温度分层和净初级生产力(NPP)来定义生物物理生物群落。利用聚类方法确定了六个生物物理生物群落。用 SEAPODYM-LMTL 模型模拟的微小浮游生物来描述这些生物物理生物群落的特征,显示了生物量与聚类中使用的环境变量之间的特定关系(即生物量主要由净初级生产力和温度构成)。生物物理生物群落也显示了模拟的微浮游生物功能群比例所暗示的特定垂直结构。然后,对生物物理生物群落的边界进行了验证,以确定相邻生物群落声学反向散射响应中潜在的垂直结构重组。区域化确定了声学垂直结构的同质区域,这些区域在相邻生物群落之间也存在差异。最后,与根据微浮游生物生物量计算出的另一种生物群落定义进行的比较表明,环境变量只能解释微浮游生物结构的部分变化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Global characterization of modelled micronekton in biophysically defined provinces
Micronekton are the mid-trophic level of the ecosystem and contribute to active carbon export to the deep ocean through diel vertical migrations. Better characterization of micronekton functional groups depending on relationships to environmental variables is useful for the management of marine resources, the conservation of biodiversity and a better understanding of climate change impacts. For this purpose, regionalization of global ocean into homogeneous provinces is an approach that is generating increasing interest. However, published regionalizations efforts (i) derived from environmental forcings, that do not specifically focus on micronekton and (ii) derived from acoustic backscatter, which do not allow direct estimates of micronekton biomass. Here, we propose to fill the gap between biophysical regionalizations and micronekton biomass. We notably defined biophysical biomes using global environmental variables known to affect micronekton: temperature of the epipelagic layer, temperature stratification, and net primary production (NPP). Six biophysical biomes were defined with a clustering method. A characterization of these biophysical biomes with simulated micronekton from the SEAPODYM-LMTL model displayed biome-specific relationships between biomass and the environmental variables used in the clustering (i.e. biomasses mostly structured by NPP and temperature). Biophysical biomes also displayed specific vertical structures suggested by modelled micronekton functional groups ratios. Then, a validation of biophysical biomes’ boundaries was performed to identify potential vertical structure reorganization in acoustic backscattering response from adjacent biomes. The regionalization identified homogeneous areas in terms of acoustic vertical structure, which were also different between adjacent biomes. Finally, a comparison with another biomes’ definition computed from micronekton biomasses suggested that environmental variables can account for only some of the variability of the micronekton structures.
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来源期刊
Progress in Oceanography
Progress in Oceanography 地学-海洋学
CiteScore
7.20
自引率
4.90%
发文量
138
审稿时长
3 months
期刊介绍: Progress in Oceanography publishes the longer, more comprehensive papers that most oceanographers feel are necessary, on occasion, to do justice to their work. Contributions are generally either a review of an aspect of oceanography or a treatise on an expanding oceanographic subject. The articles cover the entire spectrum of disciplines within the science of oceanography. Occasionally volumes are devoted to collections of papers and conference proceedings of exceptional interest. Essential reading for all oceanographers.
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