垂直和水平顶燃油连续性影响群体点火和燃油消耗

IF 3 3区 农林科学 Q2 ECOLOGY Fire-Switzerland Pub Date : 2023-08-18 DOI:10.3390/fire6080321
S. Ritter, C. Hoffman, M. Battaglia, R. Linn, W. Mell
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引用次数: 1

摘要

更深入地了解精细尺度燃料模式对火灾行为的影响,对于设计旨在减少火灾危害、提高结构复杂性、增强生态系统功能和恢复力的森林处理措施至关重要。特别相关的是水平和垂直森林结构对潜在的树木焚烧和大树死亡率的影响。可能的情况是,在空间复杂的林分中,火灾行为与基于燃料分布和结构的林分级描述符的预测不同。在这项工作中,我们使用了一个空间明确的火灾行为模型来评估燃料的垂直和水平分布如何影响火灾从地表传播到上层树冠的可能性。我们的研究结果支持这样的理解,即接近表面的树冠燃料(如针叶和小直径树枝)有助于这种转变;然而,我们通过展示层上水平燃料连通性的交互效应增加了重要的细微差别。当地表火线强度大于1415 kW/m时,水平连通性的影响超过了树冠空间低燃料的影响。例如,具有垂直连续的燃料和有限的水平连通性的树木组比具有明显的表面和冠层之间的垂直间隙但具有高冠层水平连通性的树木组持续较少的大树消耗。这种效应可能是由于上层冠层的净垂直换热减少以及水平换热减少,或冠冠间扩散。这些结果表明,垂直复杂的树冠群所代表的树冠火灾危险是由树冠群内树冠的密度或水平连通性强烈介导的,因此,管理者可能能够减轻与垂直异质树群相关的一些火灾危险。
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Vertical and Horizontal Crown Fuel Continuity Influences Group-Scale Ignition and Fuel Consumption
A deeper understanding of the influence of fine-scale fuel patterns on fire behavior is essential to the design of forest treatments that aim to reduce fire hazard, enhance structural complexity, and increase ecosystem function and resilience. Of particular relevance is the impact of horizontal and vertical forest structure on potential tree torching and large-tree mortality. It may be the case that fire behavior in spatially complex stands differs from predictions based on stand-level descriptors of the fuel distribution and structure. In this work, we used a spatially explicit fire behavior model to evaluate how the vertical and horizontal distribution of fuels influences the potential for fire to travel from the surface into overstory tree crowns. Our results support the understanding that crown fuels (e.g., needles and small-diameter branchwood) close to the surface can aid in this transition; however, we add important nuance by showing the interactive effect of overstory horizontal fuel connectivity. The influence of fuels low in the canopy space was overridden by the effect of horizontal connectivity at surface fire-line intensities greater than 1415 kW/m. For example, tree groups with vertically continuous fuels and limited horizontal connectivity sustained less large-tree consumption than tree groups with a significant vertical gap between the surface and canopy but high-canopy horizontal connectivity. This effect was likely the result of reduced net vertical heat transfer as well as decreased horizontal heat transfer, or crown-to-crown spread, in the upper canopy. These results suggest that the crown fire hazard represented by vertically complex tree groups is strongly mediated by the density, or horizontal connectivity, of the tree crowns within the group, and therefore, managers may be able to mitigate some of the torching hazard associated with vertically heterogenous tree groups.
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来源期刊
Fire-Switzerland
Fire-Switzerland Multiple-
CiteScore
3.10
自引率
15.60%
发文量
182
审稿时长
11 weeks
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