Department of Forest and Wildlife Ecology, SILVIS Lab, University of Wisconsin-Madison, Madison, Wisconsin 53706, USA.
USDA Forest Service, Rocky Mountain Research Station, Fort Collins, Colorado 80526, USA.
Ecol Appl. 2016 Dec;26(8):2718-2729. doi: 10.1002/eap.1416.
Climate conditions, such as temperature or precipitation, averaged over several decades strongly affect species distributions, as evidenced by experimental results and a plethora of models demonstrating statistical relations between species occurrences and long-term climate averages. However, long-term averages can conceal climate changes that have occurred in recent decades and may not capture actual species occurrence well because the distributions of species, especially at the edges of their range, are typically dynamic and may respond strongly to short-term climate variability. Our goal here was to test whether bird occurrence models can be predicted by either covariates based on short-term climate variability or on long-term climate averages. We parameterized species distribution models (SDMs) based on either short-term variability or long-term average climate covariates for 320 bird species in the conterminous USA and tested whether any life-history trait-based guilds were particularly sensitive to short-term conditions. Models including short-term climate variability performed well based on their cross-validated area-under-the-curve AUC score (0.85), as did models based on long-term climate averages (0.84). Similarly, both models performed well compared to independent presence/absence data from the North American Breeding Bird Survey (independent AUC of 0.89 and 0.90, respectively). However, models based on short-term variability covariates more accurately classified true absences for most species (73% of true absences classified within the lowest quarter of environmental suitability vs. 68%). In addition, they have the advantage that they can reveal the dynamic relationship between species and their environment because they capture the spatial fluctuations of species potential breeding distributions. With this information, we can identify which species and guilds are sensitive to climate variability, identify sites of high conservation value where climate variability is low, and assess how species' potential distributions may have already shifted due recent climate change. However, long-term climate averages require less data and processing time and may be more readily available for some areas of interest. Where data on short-term climate variability are not available, long-term climate information is a sufficient predictor of species distributions in many cases. However, short-term climate variability data may provide information not captured with long-term climate data for use in SDMs.
气候条件,如温度或降水,在几十年的平均值上对物种分布有很大的影响,这一点从实验结果和大量的模型中得到了证明,这些模型展示了物种出现与长期气候平均值之间的统计关系。然而,长期平均值可能掩盖了近几十年来发生的气候变化,并且可能不能很好地捕捉实际的物种出现情况,因为物种的分布,特别是在其范围的边缘,通常是动态的,并且可能对短期气候变异性有强烈的反应。我们的目标是测试鸟类出现模型是否可以通过基于短期气候变异性的协变量或基于长期气候平均值的协变量来预测。我们为美国本土的 320 种鸟类参数化了物种分布模型(SDM),这些模型基于短期变异性或长期平均气候协变量,并测试了任何基于生活史特征的类群是否对短期条件特别敏感。基于短期气候变异性的模型表现良好,其交叉验证曲线下面积 AUC 评分(0.85)与基于长期气候平均值的模型(0.84)相当。同样,与北美繁殖鸟类调查(独立 AUC 分别为 0.89 和 0.90)的独立存在/缺失数据相比,这两种模型的表现都很好。然而,基于短期变异性协变量的模型更准确地为大多数物种分类了真实的缺失值(73%的真实缺失值在环境适宜性的最低四分之一内分类,而 68%)。此外,它们还有一个优势,即它们可以揭示物种与其环境之间的动态关系,因为它们捕捉了物种潜在繁殖分布的空间波动。有了这些信息,我们可以确定哪些物种和类群对气候变异性敏感,识别出气候变异性低的高保护价值地点,并评估由于最近的气候变化,物种的潜在分布可能已经发生了变化。然而,长期气候平均值需要较少的数据和处理时间,并且对于某些感兴趣的地区可能更容易获得。在无法获得短期气候变异性数据的情况下,长期气候信息在许多情况下都是物种分布的充分预测因子。然而,短期气候变异性数据可能提供了长期气候数据无法捕捉的信息,可用于 SDM 中。
