Predicting snag fall in an old-growth forest after fire

IF 3.6 3区环境科学与生态学 Q1 ECOLOGY

Fire Ecology Pub Date : 2023-11-23 DOI:10.1186/s42408-023-00225-z

Kendall M. L. Becker, James A. Lutz

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Abstract

Snags, standing dead trees, are becoming more abundant in forests as tree mortality rates continue to increase due to fire, drought, and bark beetles. Snags provide habitat for birds and small mammals, and when they fall to the ground, the resulting logs provide additional wildlife habitat and affect nutrient cycling, fuel loads, and fire behavior. Predicting how long snags will remain standing after fire is essential for managing habitat, understanding chemical cycling in forests, and modeling forest succession and fuels. Few studies, however, have quantified how fire changes snag fall dynamics. We compared post-fire fall rates of snags that existed pre-fire (n = 2013) and snags created during or after the fire (n = 8222), using 3 years of pre-fire and 5 years of post-fire data from an annually monitored, 25.6-ha spatially explicit plot in an old-growth Abies concolor–Pinus lambertiana forest in the Sierra Nevada, CA, USA. The plot burned at low to moderate severity in the Rim Fire of 2013. We used random forest models to (1) identify predictors of post-fire snag fall for pre-existing and new snags and (2) assess the influence of spatial neighborhood and local fire severity on snag fall after fire. Fall rates of pre-existing snags increased 3 years after fire. Five years after fire, pre-existing snags were twice as likely to fall as new snags. Pre-existing snags were most likely to persist 5 years after fire if they were > 50 cm in diameter, > 20 m tall, and charred on the bole to heights above 3.7 m. New snags were also more likely to persist 5 years after fire if they were > 20 m tall. Spatial neighborhood (e.g., tree density) and local fire severity (e.g., fire-caused crown injury) within 15 m of each snag barely improved predictions of snag fall after fire. Land managers should expect fall rates of pre-existing snags to exceed fall rates of new snags within 5 years after fire, an important habitat consideration because pre-existing snags represent a wider range of size and decay classes.

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预测火灾后原始森林的树枝掉落

由于火灾、干旱和树皮甲虫等原因，树木的死亡率持续上升，森林中的枯死树木变得越来越多。障碍物为鸟类和小型哺乳动物提供栖息地，当它们落到地面时，产生的原木为野生动物提供了额外的栖息地，并影响营养循环、燃料负荷和火灾行为。预测火灾后障碍物能保持多长时间对于管理栖息地、了解森林中的化学循环以及模拟森林演替和燃料至关重要。然而，很少有研究量化了火灾变化是如何阻碍下降动力学的。我们比较了火灾前存在的障碍(n = 2013)和火灾期间或之后产生的障碍(n = 8222)的火灾后下降率，使用了来自美国内华达州塞拉山脉的一个25.6公顷空间明确的原始冷杉-蓝柏树松森林中每年监测的3年和5年的数据。该地块在2013年的“环火”(Rim Fire)中以低到中度的严重程度被烧毁。我们使用随机森林模型来(1)识别已经存在的和新的障碍的火灾后障碍下降的预测因子;(2)评估空间邻域和当地火灾严重程度对火灾后障碍下降的影响。火灾发生3年后，原有障碍的坠落率上升。火灾发生五年后，先前存在的障碍倒塌的可能性是新障碍的两倍。如果先前存在的障碍直径> 50厘米，高度> 20米，并且在洞上烧焦到3.7米以上，则最有可能在火灾后持续5年。如果新的障碍物高度大于20米，则更有可能在火灾后持续5年。距离每个树枝15米内的空间邻域(如树木密度)和当地火灾严重程度(如火灾造成的树冠损伤)几乎不能改善对火灾后树枝掉落的预测。土地管理者应该预期，在火灾发生后的5年内，已存在的障碍的下降率将超过新障碍的下降率，这是一个重要的栖息地考虑因素，因为已存在的障碍代表了更大范围的大小和腐烂类别。

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

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.