气候变化下西班牙森林燃料水分动态模拟

IF 3.6 3区环境科学与生态学 Q1 ECOLOGY

Fire Ecology Pub Date : 2023-10-27 DOI:10.1186/s42408-023-00224-0

Rodrigo Balaguer-Romano, Rubén Díaz-Sierra, Miquel De Cáceres, Jordi Voltas, Matthias M. Boer, Víctor Resco de Dios

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引用次数: 0

摘要

当前气候变化对未来野火风险影响的评估要么基于经验方法，要么基于火灾天气指数。目前还没有研究在全国范围内使用基于过程的模型来了解气候干旱的增加如何以及在哪里通过改变活燃料(LFMC)和死燃料(DFMC)的水分含量来影响火灾活动的可能性。本文采用基于过程的模式对中、高温室气体排放情景(RCP4.5和RCP8.5)下21世纪气候条件下LFMC和DFMC的变化进行了预测。在西班牙半岛进行了广泛的生产力梯度预测，以了解生产力如何介导气候变化对燃料湿度动态的影响。结果LFMC和DFMC在未来几十年的气候条件下呈下降趋势。在RCP4.5和RCP8.5下，燃料含水率低于野火发生阈值的年天数频率的增加预计将使火灾季节长度延长20天，50天。气候变化对LFMC和DFMC的影响与生产力呈线性负相关(在最低生产力环境中燃料湿度降低)。虽然我们观察到二氧化碳的增加(通过提高水利用效率)产生了显著的缓解效应，但这不足以抵消温度升高和干旱引起的LFMC下降趋势。我们预测，21世纪更加温暖和干旱的气候条件将导致燃料湿度普遍下降，火灾季节延长，野火危险增加。使用基于过程的模型来预测LFMC动态，可以考虑植物物种缓冲气候变化影响的能力。在最多产的环境中，预计火灾季节长度的显着增加，目前火灾回火间隔较大，这将增加西班牙主要碳汇的火灾危险。最后，二氧化碳减缓效应不足以抵消气候变化导致的季节性LFMC水平下降。

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Modeling fuel moisture dynamics under climate change in Spain’s forests

Abstract Background Current assessments of the effects of climate change on future wildfire risk are based on either empirical approaches or fire weather indices. No study has yet used process-based models over national scales to understand how and where will increases in climate aridity affect the likelihood of fire activity through changes in the moisture content of live (LFMC) and of dead (DFMC) fuels. Here, we used process-based models to forecast changes in LFMC and DFMC under the 21st century climatic conditions projected from moderate and high greenhouse gas emission scenarios (RCP4.5 and RCP8.5). Predictions were performed across broad productivity gradients in peninsular Spain to understand how productivity mediates the effects of climate change on fuel moisture dynamics. Results LFMC and DFMC were predicted to decline under the climatic conditions projected for the coming decades. Increases in the annual frequency of days with fuel moisture content below wildfire occurrence thresholds were predicted to extend fire season lengths by 20 days under RCP4.5 and by 50 days under RCP8.5. The effects of climate change on LFMC and DFMC varied linearly and negatively with productivity (stronger fuel moisture decreases in least productive environments). Although we observed a significant mitigation effect from rising CO 2 (via increases in water-use efficiency), it was not enough to offset LFMC declining trends induced by increased temperature and aridity. Conclusions We predicted that the warmer and more arid climatic conditions projected for the 21st century will lead to generalized declines in fuel moisture, lengthening fire seasons, and increasing wildfire danger. The use of process-based models to forecast LFMC dynamics allowed the consideration of plant species capabilities to buffer climate change impacts. Significant increases in the fire season length predicted in the most productive environments, currently with large fire return intervals, would pose an increase of fire danger in major Spanish carbon sinks. Finally, the CO 2 mitigation effect would not be enough to offset climate change-driven declines in seasonal LFMC levels.

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来源期刊

Fire Ecology ECOLOGY-FORESTRY

CiteScore

6.20

自引率

7.80%

发文量

审稿时长

20 weeks

期刊介绍： Fire Ecology is the international scientific journal supported by the Association for Fire Ecology. Fire Ecology publishes peer-reviewed articles on all ecological and management aspects relating to wildland fire. We welcome submissions on topics that include a broad range of research on the ecological relationships of fire to its environment, including, but not limited to: Ecology (physical and biological fire effects, fire regimes, etc.) Social science (geography, sociology, anthropology, etc.) Fuel Fire science and modeling Planning and risk management Law and policy Fire management Inter- or cross-disciplinary fire-related topics Technology transfer products.