Triggering Pyro-Convection in a High-Resolution Coupled Fire–Atmosphere Simulation

Fire Pub Date : 2024-03-16 DOI:10.3390/fire7030092

F. T. Couto, Jean-Baptiste Filippi, R. Baggio, Cátia Campos, Rui Salgado

{"title":"Triggering Pyro-Convection in a High-Resolution Coupled Fire–Atmosphere Simulation","authors":"F. T. Couto, Jean-Baptiste Filippi, R. Baggio, Cátia Campos, Rui Salgado","doi":"10.3390/fire7030092","DOIUrl":null,"url":null,"abstract":"This study aimed to assess fire–atmosphere interactions using the fully coupled Meso-NH–ForeFire system. We focused on the Pedrógão Grande wildfire (28,914 ha), which occurred in June 2017 and was one of the deadliest and most damaging fires in Portugal’s history. Two simulations (control and fully coupled fire–atmosphere) were performed for three two-way nested domains configured with horizontal resolutions of 2 km, 0.4 km, and 0.08 km, respectively, in the atmospheric model Meso-NH. Fire propagation was modeled within the innermost domain with ForeFire, which solves the fire front with a 20 m resolution, producing the heat and vapor fluxes which are then injected into the atmospheric model. A simplified homogeneous fuel distribution was used in this case study. The fully coupled experiment helped us to characterize the smoke plume structure and identify two different regimes: (1) a wind-driven regime, with the smoke plume transported horizontally southward and in the lower troposphere, and (2) a plume-dominated regime, in which the simulated smoke plume extended vertically up to upper levels, favoring the formation of a pyro-cloud. The simulations were compared, and the results suggest that the change in the fire regime was caused by an outflow that affected the main fire front. Furthermore, the fully coupled simulation allowed us to explore the change in meteorology caused by an extreme fire, namely through the development of a pyro-cloud that also induced outflows that reached the surface. We show that the Meso-NH–ForeFire system may strongly contribute to an improved understanding of extreme wildfires events and associated weather phenomena.","PeriodicalId":12279,"journal":{"name":"Fire","volume":"100 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-03-16","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Fire","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.3390/fire7030092","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 0

Abstract

This study aimed to assess fire–atmosphere interactions using the fully coupled Meso-NH–ForeFire system. We focused on the Pedrógão Grande wildfire (28,914 ha), which occurred in June 2017 and was one of the deadliest and most damaging fires in Portugal’s history. Two simulations (control and fully coupled fire–atmosphere) were performed for three two-way nested domains configured with horizontal resolutions of 2 km, 0.4 km, and 0.08 km, respectively, in the atmospheric model Meso-NH. Fire propagation was modeled within the innermost domain with ForeFire, which solves the fire front with a 20 m resolution, producing the heat and vapor fluxes which are then injected into the atmospheric model. A simplified homogeneous fuel distribution was used in this case study. The fully coupled experiment helped us to characterize the smoke plume structure and identify two different regimes: (1) a wind-driven regime, with the smoke plume transported horizontally southward and in the lower troposphere, and (2) a plume-dominated regime, in which the simulated smoke plume extended vertically up to upper levels, favoring the formation of a pyro-cloud. The simulations were compared, and the results suggest that the change in the fire regime was caused by an outflow that affected the main fire front. Furthermore, the fully coupled simulation allowed us to explore the change in meteorology caused by an extreme fire, namely through the development of a pyro-cloud that also induced outflows that reached the surface. We show that the Meso-NH–ForeFire system may strongly contribute to an improved understanding of extreme wildfires events and associated weather phenomena.

查看原文本刊更多论文

在高分辨率火灾-大气耦合模拟中触发火热对流

本研究旨在利用完全耦合的中-北半球-森林火灾系统评估火灾与大气之间的相互作用。我们重点研究了 2017 年 6 月发生的 Pedrógão Grande 野火（28,914 公顷），这是葡萄牙历史上死亡人数最多、破坏最严重的火灾之一。在大气模型Meso-NH中，对水平分辨率分别为2千米、0.4千米和0.08千米的三个双向嵌套域进行了两次模拟（控制和火灾-大气完全耦合）。在最内层域中，使用 ForeFire 对火灾传播进行建模，ForeFire 以 20 米的分辨率对火灾前沿进行求解，产生热通量和水汽通量，然后将其注入大气模型。本案例研究采用了简化的均质燃料分布。完全耦合实验帮助我们确定了烟羽结构的特征，并确定了两种不同的状态：(1) 风驱动状态，烟羽水平向南移动，位于对流层下部；(2) 烟羽主导状态，模拟烟羽垂直延伸至高层，有利于形成火烧云。对模拟结果进行了比较，结果表明，火势变化是由影响主火线的外流引起的。此外，通过完全耦合模拟，我们还探索了极端火灾引起的气象变化，即火烧云的形成也诱发了到达地表的外流。我们的研究表明，Meso-NH-ForeFire 系统可以极大地促进对极端野火事件及相关天气现象的理解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Fire

自引率

0.00%

发文量