Fire effects on geomorphic processes

Luke A. McGuire, Brian A. Ebel, Francis K. Rengers, Diana C. S. Vieira, Petter Nyman
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Abstract

Fire-induced geomorphic changes, such as enhanced erosion and debris-flow activity, are expected to increase with climate change owing to increases in fire activity and rainfall intensification. In this Review, we summarize how landscape attributes, rainfall and burn severity influence post-fire geomorphic responses over a range of temporal and spatial scales. Sub-hourly rainfall intensity and burn severity control the magnitude of many post-fire geomorphic process rates through their influence on ground cover and rainfall-runoff partitioning. Post-fire debris flows (PFDFs) make a substantial contribution to the post-fire sediment cascade, transporting sediment from hillslopes to channels, adjacent floodplains and alluvial fans. By the late twenty-first century, PFDF activity is estimated to increase in 68% of areas in which PFDFs have occurred in the past and decrease in only 2% of locations. Once altered by fire, geomorphic state variables — such as infiltration capacity, canopy cover, ground cover and sediment availability — can recover to their pre-fire value or be shifted to a new value. Improved understanding of the factors that influence these post-fire trajectories could support targeted management and intervention strategies. Additionally, monitoring that extends beyond the first 1–3 years after fire and deeper integration of ecohydrological processes into geomorphic models are needed to improve forecasts of post-fire geomorphic responses. Fire can increase the rates of geomorphic processes leading to rapid landscape change and sediment-related hazards. This Review outlines the factors and processes that influence the magnitude, temporal persistence and extent of fire-induced geomorphic changes.

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Abstract Image

火灾对地貌过程的影响
由于火灾活动增加和降雨加剧,预计火灾引起的地貌变化(如侵蚀和泥石流活动增强)将随着气候变化而加剧。在本综述中,我们总结了景观属性、降雨量和燃烧严重程度如何在一系列时间和空间尺度上影响火灾后的地貌响应。亚小时降雨强度和燃烧严重程度通过对地面覆盖和降雨-径流分区的影响,控制着许多火后地貌过程速率的大小。火灾后的泥石流(PFDFs)对火灾后的沉积物级联做出了重大贡献,将沉积物从山坡运送到河道、邻近的洪泛平原和冲积扇。据估计,到二十一世纪末,在过去曾发生过 PFDF 的地区中,有 68% 的地区 PFDF 活动会增加,只有 2% 的地区会减少。地貌状态变量(如渗透能力、树冠覆盖率、地面覆盖率和沉积物可用性)一旦被火灾改变,就会恢复到火灾前的值,或转变为新的值。更好地了解影响这些火灾后轨迹的因素可以支持有针对性的管理和干预策略。此外,需要在火灾发生后的最初 1-3 年进行监测,并将生态水文过程更深入地纳入地貌模型,以改进对火灾后地貌反应的预测。
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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