火灾易发荒地和泥炭地景观对燃料水分变化的景观控制

IF 3.6 3区 环境科学与生态学 Q1 ECOLOGY
Kerryn Little, Laura J Graham, Mike Flannigan, Claire M Belcher, Nicholas Kettridge
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引用次数: 0

摘要

跨地形的燃料水分含量变化很大,但在现有的火灾危险评估中却没有考虑到这一点。把握燃料湿度的复杂性及其相关控制因素,对于了解受当地异质性影响的新兴火灾易发环境中的野火行为和危险性至关重要。这对于温带荒漠地和泥炭地景观来说尤其如此,因为它们具有全球重要意义的碳储存对野火的脆弱性存在空间差异。在这里,我们通过在英国北约克郡沼泽地进行的密集燃料水分取样活动,量化了温带火灾易发地貌中Calluna vulgaris的活和死燃料水分的变化范围。我们还首次评估了温带热地和泥炭地景观燃料水分变化的景观(土壤质地、树冠年龄、地势和坡度)和微气象(温度、相对湿度、蒸气压差和风速)驱动因素。我们观察到跨地貌的燃料水分变化很大,这在野火蔓延的活燃料可用性(燃料水分小于 65%)和有机层易燃性(燃料水分小于 250%)方面造成了空间上的不连续性。这种异质性在春季最为重要,春季也是这些温带生态系统的野火高峰期。景观和微气象因素解释了高达 72% 的空间燃料水分变化,并且与季节和燃料层有关。景观因素主要控制空间燃料水分含量,而不是改变当地的微观气象。考虑景观与燃料水分的直接关系可以改进燃料水分的估算,因为现有的仅从微观气象观测得出的估算将排除景观特征的潜在影响。我们假设,土壤质地、树冠年龄和坡度的差异在所考察的燃料层中起着重要作用,而过程的主要差异则出现在活燃料、死燃料和地表/地面燃料之间。我们还强调了燃料物候学在评估温带环境中景观燃料水分变化中的关键作用。了解了燃料水分变化的驱动机制,我们就有机会开发出适合当地情况的燃料模型,并将其输入野火危险等级系统,从而增加野火危险评估作为管理工具的多功能性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Landscape controls on fuel moisture variability in fire-prone heathland and peatland landscapes
Cross-landscape fuel moisture content is highly variable but not considered in existing fire danger assessments. Capturing fuel moisture complexity and its associated controls is critical for understanding wildfire behavior and danger in emerging fire-prone environments that are influenced by local heterogeneity. This is particularly true for temperate heathland and peatland landscapes that exhibit spatial differences in the vulnerability of their globally important carbon stores to wildfire. Here we quantified the range of variability in the live and dead fuel moisture of Calluna vulgaris across a temperate fire-prone landscape through an intensive fuel moisture sampling campaign conducted in the North Yorkshire Moors, UK. We also evaluated the landscape (soil texture, canopy age, aspect, and slope) and micrometeorological (temperature, relative humidity, vapor pressure deficit, and windspeed) drivers of landscape fuel moisture variability for temperate heathlands and peatlands for the first time. We observed high cross-landscape fuel moisture variation, which created a spatial discontinuity in the availability of live fuels for wildfire spread (fuel moisture < 65%) and vulnerability of the organic layer to smoldering combustion (fuel moisture < 250%). This heterogeneity was most important in spring, which is also the peak wildfire season in these temperate ecosystems. Landscape and micrometeorological factors explained up to 72% of spatial fuel moisture variation and were season- and fuel-layer-dependent. Landscape factors predominantly controlled spatial fuel moisture content beyond modifying local micrometeorology. Accounting for direct landscape–fuel moisture relationships could improve fuel moisture estimates, as existing estimates derived solely from micrometeorological observations will exclude the underlying influence of landscape characteristics. We hypothesize that differences in soil texture, canopy age, and aspect play important roles across the fuel layers examined, with the main differences in processes arising between live, dead, and surface/ground fuels. We also highlight the critical role of fuel phenology in assessing landscape fuel moisture variations in temperate environments. Understanding the mechanisms driving fuel moisture variability opens opportunities to develop locally robust fuel models for input into wildfire danger rating systems, adding versatility to wildfire danger assessments as a management tool.
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来源期刊
Fire Ecology
Fire Ecology ECOLOGY-FORESTRY
CiteScore
6.20
自引率
7.80%
发文量
24
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.
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