将 GOES-16 火灾辐射功率检索结果纳入烟雾预报系统 (WoFS-Smoke)

IF 2.9 3区 农林科学 Q1 FORESTRY International Journal of Wildland Fire Pub Date : 2024-01-25 DOI:10.1071/wf23133
Thomas Jones, Ravan Ahmadov, Eric James, Gabriel Pereira, Saulo Freitas, Georg Grell
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引用次数: 0

摘要

背景美国近年来野火的数量创下了历史新高,这促使人们更加关注开发工具,以便在高空间和时间分辨率下准确预测野火的影响。开发烟雾预报系统(WoFS-Smoke)的目的是利用从卫星获取的野火特性在系统中生成烟羽,从而改进这些预报。方法烟雾预报系统是一个区域域集合数据同化和预报系统,其概念是创建短期(0-6 小时)高影响天气预报。这项工作对 WoFS-Smoke 进行了扩展,以 15 分钟的间隔从 GOES-16 卫星获取数据,对野火相关的快速变化条件进行采样。主要结果有 GOES-16 数据和没有 GOES-16 数据的实验比较表明,摄入高时间频率数据可使野火更早进入模型,从而改善野火早期阶段的烟雾预报。与火势减弱相关的烟羽强度下降也得到了更好的预测。结论科罗拉多州博尔德附近的大火和德克萨斯州、俄克拉荷马州和阿肯色州的多起火灾结果一致,表明该系统具有广泛的适用性。意义利用地球静止卫星数据开发 WoFS-Smoke 系统可大大推进烟雾预报及其下游影响(如空气质量下降、能见度降低以及严重对流的潜在特性)。
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Ingesting GOES-16 fire radiative power retrievals into Warn-on-Forecast System for Smoke (WoFS-Smoke)
Background

The record number of wildfires in the United States in recent years has led to an increased focus on developing tools to accurately forecast their impacts at high spatial and temporal resolutions.

Aims

The Warn-on-Forecast System for Smoke (WoFS-Smoke) was developed to improve these forecasts using wildfire properties retrieved from satellites to generate smoke plumes in the system.

Methods

The WoFS is a regional domain ensemble data assimilation and forecasting system built around the concept of creating short-term (0–6 h) forecasts of high impact weather. This work extends WoFS-Smoke by ingesting data from the GOES-16 satellite at 15-min intervals to sample the rapidly changing conditions associated with wildfires.

Key results

Comparison of experiments with and without GOES-16 data show that ingesting high temporal frequency data allows for wildfires to be initiated in the model earlier, leading to improved smoke forecasts during their early phases. Decreasing smoke plume intensity associated with weakening fires was also better forecast.

Conclusions

The results were consistent for a large fire near Boulder, Colorado and a multi-fire event in Texas, Oklahoma, and Arkansas, indicating a broad applicability of this system.

Implications

The development of WoFS-Smoke using geostationary satellite data allows for a significant advancement in smoke forecasting and its downstream impacts such as reductions in air quality, visibility, and potentially properties of severe convection.

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来源期刊
CiteScore
5.50
自引率
9.70%
发文量
67
审稿时长
12-24 weeks
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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