Declining ecological resilience and invasion resistance under climate change in the sagebrush region, United States

IF 4.3 2区环境科学与生态学 Q1 ECOLOGY

Ecological Applications Pub Date : 2024-11-25 DOI:10.1002/eap.3065

Daniel R. Schlaepfer, Jeanne C. Chambers, Alexandra K. Urza, Brice B. Hanberry, Jessi L. Brown, David I. Board, Steven B. Campbell, Karen J. Clause, Michele R. Crist, John B. Bradford

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引用次数: 0

Abstract

In water‐limited dryland ecosystems of the Western United States, climate change is intensifying the impacts of heat, drought, and wildfire. Disturbances often lead to increased abundance of invasive species, in part, because dryland restoration and rehabilitation are inhibited by limited moisture and infrequent plant recruitment events. Information on ecological resilience to disturbance (recovery potential) and resistance to invasive species can aid in addressing these challenges by informing long‐term restoration and conservation planning. Here, we quantified the impacts of projected future climate on ecological resilience and invasion resistance (R&R) in the sagebrush region using novel algorithms based on ecologically relevant and climate‐sensitive predictors of climate and ecological drought. We used a process‐based ecohydrological model to project these predictor variables and resulting R&R indicators for two future climate scenarios and 20 climate models. Results suggested widespread future R&R decreases (24%–34% of the 1.16 million km2 study area) that are generally consistent among climate models. Variables related to rising temperatures were most strongly linked to decreases in R&R indicators. New continuous R&R indices quantified responses to climate change; particularly useful for areas without projected change in the R&R category but where R&R still may decrease, for example, some of the areas with a historically low R&R category. Additionally, we found that areas currently characterized as having high sagebrush ecological integrity had the largest areal percentage with expected declines in R&R in the future, suggesting continuing declines in sagebrush ecosystems. One limitation of these R&R projections was relatively novel future climatic conditions in particularly hot and dry areas that were underrepresented in the training data. Including more data from these areas in future updates could further improve the reliability of the projections. Overall, these projected future declines in R&R highlight a growing challenge for natural resource managers in the region, and the resulting spatially explicit datasets provide information that can improve long‐term risk assessments, prioritizations, and climate adaptation efforts.

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气候变化下美国鼠尾草地区生态复原力和抵御入侵能力的下降

在美国西部水资源有限的旱地生态系统中，气候变化正在加剧高温、干旱和野火的影响。干扰通常会导致入侵物种的增加，部分原因是旱地的恢复和复原受到有限的水分和不频繁的植物繁殖活动的抑制。有关生态对干扰的恢复力（恢复潜力）和对入侵物种的抵抗力的信息可以为长期恢复和保护规划提供信息，从而帮助应对这些挑战。在这里，我们使用基于生态相关和气候敏感的气候与生态干旱预测因子的新型算法，量化了预测的未来气候对鼠尾草地区生态恢复力和入侵抵抗力（R&R）的影响。我们使用基于过程的生态水文模型，针对两种未来气候情景和 20 种气候模型，预测这些预测变量和由此产生的 R&R 指标。结果表明，未来 R&R 普遍下降（116 万平方公里研究区域的 24%-34%），各气候模型之间基本一致。与气温上升相关的变量与 R&R 指标下降的关系最为密切。新的连续 R&R 指数量化了对气候变化的反应；对于 R&R 类别预计不会发生变化但 R&R 仍可能下降的地区（例如，一些 R&R 类别历史上较低的地区）尤其有用。此外，我们还发现，目前具有高沙棘生态完整性的地区，其 R&R 预计在未来下降的面积比例最大，这表明沙棘生态系统仍在继续衰退。这些 R&R 预测的一个局限性是在特别炎热和干旱地区的未来气候条件相对较新，而这些地区在训练数据中的代表性不足。在未来的更新中纳入更多来自这些地区的数据可以进一步提高预测的可靠性。总之，这些预测的未来 R&R 下降突显了该地区自然资源管理者面临的日益严峻的挑战，由此产生的空间明确数据集提供的信息可以改善长期风险评估、优先排序和气候适应工作。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Ecological Applications 环境科学-环境科学

CiteScore

9.50

自引率

2.00%

发文量

268

审稿时长

6 months

期刊介绍： The pages of Ecological Applications are open to research and discussion papers that integrate ecological science and concepts with their application and implications. Of special interest are papers that develop the basic scientific principles on which environmental decision-making should rest, and those that discuss the application of ecological concepts to environmental problem solving, policy, and management. Papers that deal explicitly with policy matters are welcome. Interdisciplinary approaches are encouraged, as are short communications on emerging environmental challenges.