High-Latitude Eddy Covariance Temporal Network Design and Optimization

IF 3.7 3区 环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES Journal of Geophysical Research: Biogeosciences Pub Date : 2024-10-25 DOI:10.1029/2024JG008406
Martijn M. T. A. Pallandt, Martin Jung, Kyle Arndt, Susan M. Natali, Brendan M. Rogers, Anna-Maria Virkkala, Mathias Göckede
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Abstract

Ecosystems at high latitudes are changing rapidly in response to climate change. To understand changes in carbon fluxes across seasonal to multi-decadal timescales, long-term in situ measurements from eddy covariance networks are needed. However, there are large spatiotemporal gaps in the high-latitude eddy covariance network. Here we used the relative extrapolation error index in machine learning-based upscaled gross primary production as a measure of network representativeness and as the basis for a network optimization. We show that the relative extrapolation error index has steadily decreased from 2001 to 2020, suggesting diminishing upscaling errors. In experiments where we limit site activity by either setting a maximum duration or by ending measurements at a fixed time those errors increase significantly, in some cases setting the network status back more than a decade. Our experiments also show that with equal site activity across different theoretical network setups, a more spread out design with shorter-term measurements functions better in terms of larger-scale representativeness than a network with fewer long-term towers. We developed a method to select optimized site additions for a network extension, which blends an objective modeling approach with expert knowledge. This method greatly outperforms an unguided network extension and can compensate for suboptimal human choices. For the Canadian Arctic we show several optimization scenarios and find that especially the Canadian high Arctic and north east tundra benefit greatly from addition sites. Overall, it is important to keep sites active and where possible make the extra investment to survey new strategic locations.

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高纬度涡协方差时空网络设计与优化
高纬度地区的生态系统正随着气候变化而迅速变化。要了解碳通量在季节到数十年时间尺度上的变化,需要通过涡度协方差网络进行长期的实地测量。然而,高纬度涡度协方差网络存在巨大的时空差距。在这里,我们使用基于机器学习的上标初级生产总量中的相对外推误差指数来衡量网络的代表性,并将其作为网络优化的基础。我们发现,从 2001 年到 2020 年,相对外推误差指数稳步下降,这表明上推误差正在减小。在我们通过设置最长持续时间或在固定时间结束测量来限制站点活动的实验中,这些误差显著增加,在某些情况下,网络状态倒退了十多年。我们的实验还表明,在不同的理论网络设置中,如果站点活动相同,那么在更大范围的代表性方面,具有较短时间测量的更分散的设计要比具有较少长期塔的网络更好。我们开发了一种为网络扩展选择优化站点添加的方法,该方法将客观建模方法与专家知识相结合。这种方法大大优于无指导的网络扩展,并能弥补人类的次优选择。在加拿大北极地区,我们展示了几种优化方案,发现尤其是加拿大北极高纬度地区和东北苔原地区从新增站点中获益匪浅。总之,保持站点的活跃性非常重要,并在可能的情况下进行额外投资,勘测新的战略地点。
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来源期刊
Journal of Geophysical Research: Biogeosciences
Journal of Geophysical Research: Biogeosciences Earth and Planetary Sciences-Paleontology
CiteScore
6.60
自引率
5.40%
发文量
242
期刊介绍: JGR-Biogeosciences focuses on biogeosciences of the Earth system in the past, present, and future and the extension of this research to planetary studies. The emerging field of biogeosciences spans the intellectual interface between biology and the geosciences and attempts to understand the functions of the Earth system across multiple spatial and temporal scales. Studies in biogeosciences may use multiple lines of evidence drawn from diverse fields to gain a holistic understanding of terrestrial, freshwater, and marine ecosystems and extreme environments. Specific topics within the scope of the section include process-based theoretical, experimental, and field studies of biogeochemistry, biogeophysics, atmosphere-, land-, and ocean-ecosystem interactions, biomineralization, life in extreme environments, astrobiology, microbial processes, geomicrobiology, and evolutionary geobiology
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