Dwi M. J. Purnomo, Eirik G. Christensen, Nieves Fernandez-Anez, Guillermo Rein
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引用次数: 0
摘要
背景泥炭地野火可持续数月,并对气候变化产生正反馈。这些无火焰、燃烧缓慢的大火会横向和纵向蔓延,并受到泥炭含水量的强烈影响。大多数模型都忽略了泥炭水分的非均匀性。目的我们对水分含量水平变化的泥炭烟火的蔓延行为进行了计算研究。方法我们开发了一种名为 BARA 的离散蜂窝自动机模型,并根据实验室实验对其进行了校准。主要结果BARA在预测非均匀湿度条件下的火势蔓延方面表现出很高的准确性,观察到的形状与预测到的形状有80%的相似性,并且捕捉到了复杂的现象。BARA 在 3 分钟内模拟了泥炭燃烧 1 小时的情况,显示了其在现场规模建模方面的潜力。结论我们的研究结果表明:(i) 湿度分布在决定烟熏行为中起着关键作用;(ii) 将泥炭湿度分布纳入 BARA 的简单规则可实现对烟熏扩散的可靠预测;(iii) 鉴于 BARA 的高精确度和低计算要求,可将其推广到野外应用中。意义BARA 有助于我们了解泥炭地野火及其内在驱动因素。BARA 可以成为泥炭地早期火灾预警系统的一部分。
BARA: cellular automata simulation of multidimensional smouldering in peat with horizontally varying moisture contents
Background
Smouldering peatland wildfires can last for months and create a positive feedback for climate change. These flameless, slow-burning fires spread horizontally and vertically and are strongly influenced by peat moisture content. Most models neglect the non-uniform nature of peat moisture.
Aims
We conducted a computational study into the spread behaviour of smouldering peat with horizontally varying moisture contents.
Methods
We developed a discrete cellular automaton model called BARA, and calibrated it against laboratory experiments.
Key results
BARA demonstrated high accuracy in predicting fire spread under non-uniform moisture conditions, with >80% similarity between observed and predicted shapes, and captured complex phenomena. BARA simulated 1 h of peat smouldering in 3 min, showing its potential for field-scale modelling.
Conclusion
Our findings demonstrate: (i) the critical role of moisture distribution in determining smouldering behaviour; (ii) incorporating peat moisture distribution into BARA’s simple rules achieved reliable predictions of smouldering spread; (iii) given its high accuracy and low computational requirement, BARA can be upscaled to field applications.
Implications
BARA contributes to our understanding of peatland wildfires and their underlying drivers. BARA could form part of an early fire warning system for peatland.
期刊介绍:
International Journal of Wildland Fire publishes new and significant articles that advance basic and applied research concerning wildland fire. Published papers aim to assist in the understanding of the basic principles of fire as a process, its ecological impact at the stand level and the landscape level, modelling fire and its effects, as well as presenting information on how to effectively and efficiently manage fire. The journal has an international perspective, since wildland fire plays a major social, economic and ecological role around the globe.
The International Journal of Wildland Fire is published on behalf of the International Association of Wildland Fire.
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