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阿拉斯加湾非稳定的气候-鲑鱼关系。

Non-stationary climate-salmon relationships in the Gulf of Alaska.

机构信息

College of Fisheries and Ocean Sciences, University of Alaska Fairbanks, Kodiak, AK 99615, USA

Farallon Institute for Advanced Ecosystem Research, Petaluma, CA 94952, USA.

出版信息

Proc Biol Sci. 2018 Nov 7;285(1890):20181855. doi: 10.1098/rspb.2018.1855.

DOI:10.1098/rspb.2018.1855
PMID:30404879
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6235052/
Abstract

Studies of climate effects on ecology often account for non-stationarity in individual physical and biological variables, but rarely allow for non-stationary relationships among variables. Here, we show that non-stationary relationships among physical and biological variables are central to understanding climate effects on salmon ( spp.) in the Gulf of Alaska during 1965-2012. The relative importance of two leading patterns in North Pacific climate, the Pacific Decadal Oscillation (PDO) and North Pacific Gyre Oscillation (NPGO), changed around 1988/1989 as reflected by changing correlations with leading axes of sea surface temperature variability. Simultaneously, relationships between the PDO and Gulf of Alaska environmental variables weakened, and long-standing temperature-salmon and PDO-salmon covariance declined to zero. We propose a mechanistic explanation for changing climate-salmon relationships in terms of non-stationary atmosphere-ocean interactions coinciding with changing PDO-NPGO relative importance. We also show that regression models assuming stationary climate-salmon relationships are inappropriate over the multidecadal time scale we consider. Relaxing assumptions of stationary relationships markedly improved modelling of climate effects on salmon catches and productivity. Attempts to understand the implications of changing climate patterns in other ecosystems might also be aided by the application of models that allow associations among environmental and biological variables to change over time.

摘要

对生态气候影响的研究通常会考虑到个别物理和生物变量的非平稳性,但很少允许变量之间存在非平稳关系。在这里,我们表明,物理和生物变量之间的非平稳关系是理解 1965-2012 年阿拉斯加湾鲑鱼( spp.)对气候影响的关键。北太平洋气候的两个主要模式,太平洋年代际振荡(PDO)和北太平洋旋度振荡(NPGO)的相对重要性在 1988/1989 年左右发生了变化,这反映在与海面温度变化主导轴的相关关系的变化上。同时,PDO 与阿拉斯加湾环境变量之间的关系减弱,长期存在的温度-鲑鱼和 PDO-鲑鱼协方差下降到零。我们提出了一个关于气候变化与鲑鱼关系变化的机制解释,即非平稳的大气-海洋相互作用与 PDO-NPGO 相对重要性的变化同时发生。我们还表明,在我们考虑的多十年时间尺度上,假设气候-鲑鱼关系稳定的回归模型是不合适的。放宽对气候对鲑鱼捕捞和生产力影响的关系的假设,显著提高了模型的预测能力。在其他生态系统中,试图理解气候变化模式的影响,也可能会受益于应用允许环境和生物变量之间的关联随时间变化的模型。

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