Proximal microclimate: Moving beyond spatiotemporal resolution improves ecological predictions

IF 6.3 1区 环境科学与生态学 Q1 ECOLOGY Global Ecology and Biogeography Pub Date : 2024-06-26 DOI:10.1111/geb.13884
David H. Klinges, J. Alex Baecher, Jonas J. Lembrechts, Ilya M. D. Maclean, Jonathan Lenoir, Caroline Greiser, Michael Ashcroft, Luke J. Evans, Michael R. Kearney, Juha Aalto, Isabel C. Barrio, Pieter De Frenne, Joannès Guillemot, Kristoffer Hylander, Tommaso Jucker, Martin Kopecký, Miska Luoto, Martin Macek, Ivan Nijs, Josef Urban, Liesbeth van den Brink, Pieter Vangansbeke, Jonathan Von Oppen, Jan Wild, Julia Boike, Rafaella Canessa, Marcelo Nosetto, Alexey Rubtsov, Jhonatan Sallo-Bravo, Brett R. Scheffers
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Abstract

Aim

The scale of environmental data is often defined by their extent (spatial area, temporal duration) and resolution (grain size, temporal interval). Although describing climate data scale via these terms is appropriate for most meteorological applications, for ecology and biogeography, climate data of the same spatiotemporal resolution and extent may differ in their relevance to an organism. Here, we propose that climate proximity, or how well climate data represent the actual conditions that an organism is exposed to, is more important for ecological realism than the spatiotemporal resolution of the climate data.

Location

Temperature comparison in nine countries across four continents; ecological case studies in Alberta (Canada), Sabah (Malaysia) and North Carolina/Tennessee (USA).

Time Period

1960–2018.

Major Taxa Studied

Case studies with flies, mosquitoes and salamanders, but concepts relevant to all life on earth.

Methods

We compare the accuracy of two macroclimate data sources (ERA5 and WorldClim) and a novel microclimate model (microclimf) in predicting soil temperatures. We then use ERA5, WorldClim and microclimf to drive ecological models in three case studies: temporal (fly phenology), spatial (mosquito thermal suitability) and spatiotemporal (salamander range shifts) ecological responses.

Results

For predicting soil temperatures, microclimf had 24.9% and 16.4% lower absolute bias than ERA5 and WorldClim respectively. Across the case studies, we find that increasing proximity (from macroclimate to microclimate) yields a 247% improvement in performance of ecological models on average, compared to 18% and 9% improvements from increasing spatial resolution 20-fold, and temporal resolution 30-fold respectively.

Main Conclusions

We propose that increasing climate proximity, even if at the sacrifice of finer climate spatiotemporal resolution, may improve ecological predictions. We emphasize biophysically informed approaches, rather than generic formulations, when quantifying ecoclimatic relationships. Redefining the scale of climate through the lens of the organism itself helps reveal mechanisms underlying how climate shapes ecological systems.

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近端小气候:超越时空分辨率,改善生态预测
环境数据的尺度通常由其范围(空间面积、时间长度)和分辨率(粒度、时间间隔)来定义。虽然通过这些术语来描述气候数据的尺度适用于大多数气象应用,但对于生态学和生物地理学来说,具有相同时空分辨率和范围的气候数据在与生物体的相关性方面可能会有所不同。在此,我们建议,对于生态学的现实性而言,气候接近性(或气候数据对生物体所处实际条件的代表程度)比气候数据的时空分辨率更为重要。
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来源期刊
Global Ecology and Biogeography
Global Ecology and Biogeography 环境科学-生态学
CiteScore
12.10
自引率
3.10%
发文量
170
审稿时长
3 months
期刊介绍: Global Ecology and Biogeography (GEB) welcomes papers that investigate broad-scale (in space, time and/or taxonomy), general patterns in the organization of ecological systems and assemblages, and the processes that underlie them. In particular, GEB welcomes studies that use macroecological methods, comparative analyses, meta-analyses, reviews, spatial analyses and modelling to arrive at general, conceptual conclusions. Studies in GEB need not be global in spatial extent, but the conclusions and implications of the study must be relevant to ecologists and biogeographers globally, rather than being limited to local areas, or specific taxa. Similarly, GEB is not limited to spatial studies; we are equally interested in the general patterns of nature through time, among taxa (e.g., body sizes, dispersal abilities), through the course of evolution, etc. Further, GEB welcomes papers that investigate general impacts of human activities on ecological systems in accordance with the above criteria.
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