Multi-scale numerical simulations of the synoptic environment, Diablo windstorm, and wildfire formation mechanisms for the Tubbs Fire (2017)

IF 1.9 4区 地球科学 Q3 METEOROLOGY & ATMOSPHERIC SCIENCES Meteorology and Atmospheric Physics Pub Date : 2024-01-03 DOI:10.1007/s00703-023-01001-z
Jackson T. Wiles, Yuh-Lang Lin, Michael L. Kaplan
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Abstract

The Advanced Research Weather Research and Forecasting (WRF-ARW) model was used to simulate the downscale evolving atmospheric dynamical processes conducive to the intensification and propagation of the Tubbs Fire (2017). This wildfire impacted Napa and Sonoma Counties, California, spreading quickly and erratically through complex mountainous terrain due in large part to downslope Diablo Winds. The Tubbs Fire spread over 36,000 acres and destroyed 5,636 structures, killing 22. The simulations and supporting observations during the pre-Diablo Wind period indicate a well-defined inverted surface trough in Northern California’s Central Valley, along with a strong amplifying trough in the mid-troposphere and attendant cold frontogenesis over the Sierra Nevada. Mid-upper tropospheric jet streak flow, along with simulated and observed soundings from Reno, Nevada, indicate a mid-upper tropospheric jet indirect, exit-region descending, secondary circulation in conjunction with lower mid-tropospheric cold air advection caused by the southwestward low-level jet under the upper level jet’s entrance region. These adjustments enabled the organization of a deepening and ascending inversion over the Sierra Nevada, as well as a self-induced wave critical layer between 850 and 700 hPa prior to Diablo Wind formation. As the organizing jet streak departed, the discontinuously stratified atmosphere over the Sierra Nevada and coastal mountains in Northern California provided a favorable environment for mountain wave amplification. Intensifying leeside sinking motion coupled with wave steepening resulted in strong downslope winds in Northern California. Upward propagating mountain waves are present coinciding with the steepening of the isentropic surfaces consistent with the resonant interaction of nonlinear gravity waves. The model also simulated the development of a hydraulic jump in the lower troposphere on the lee side of the mountain range during Diablo Wind development. The simulation and observations indicate that the favorable environment for Diablo Winds resulted from the baroclinic jet-front system propagating over the Sierra Nevada when it produced a highly discontinuously stratified atmosphere favorable for nonlinear mountain wave amplification. However, the main surge of momentum down the leeside is only indirectly coupled with the jet streak’s exit region, being the result of cold frontogenesis, which allows for vertically differential cold air advection and its attendant discontinuously stratified vertical atmospheric structure.

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多尺度数值模拟图布斯大火的同步环境、暗黑风暴和野火形成机制(2017 年)
高级研究天气研究和预报(WRF-ARW)模型被用于模拟有利于 Tubbs 火灾(2017 年)加剧和传播的下尺度演变大气动力学过程。这场野火影响了加利福尼亚州的纳帕县和索诺玛县,在很大程度上由于下坡暗黑风的作用,野火在复杂的山区地形中迅速而不规则地蔓延。Tubbs 大火蔓延了 36,000 英亩,烧毁了 5,636 座建筑,造成 22 人死亡。迪亚波罗风前期的模拟和辅助观测结果表明,北加州中央山谷出现了一个清晰的倒转地表槽,同时对流层中层出现了一个强烈的放大槽,内华达山脉上空也随之出现了冷锋。对流层中上层喷流条纹流以及来自内华达州雷诺的模拟和观测探测结果表明,对流层中上层喷流间接、出口区域下降、次级环流与对流层中下层冷空气平流共同作用,由高层喷流入口区域下的西南向低层喷流引起。这些调整使得内华达山脉上空的反常现象不断加深和上升,并在暗黑破坏风形成之前,在 850 和 700 hPa 之间形成了一个自导波临界层。当组织喷流条纹离开时,内华达山脉和北加州沿海山脉上空的不连续分层大气为山地波放大提供了有利环境。不断加强的左侧下沉运动加上波浪的陡峭化导致了北加州强劲的下坡风。在等熵面陡峭化的同时,出现了向上传播的山波,这与非线性重力波的共振相互作用是一致的。该模型还模拟了在迪亚波罗风的发展过程中,山脉靠山一侧对流层下部出现的水力跃迁。模拟和观测结果表明,迪亚波罗风的有利环境来自于在内华达山脉上空传播的条气流喷射锋系统,当时它产生了有利于非线性山波放大的高度不连续分层大气。然而,左侧的主要动量涌流只是与喷流条纹的出口区域间接耦合,是冷锋生成的结果,这使得垂直差异冷空气平流和随之而来的不连续分层垂直大气结构成为可能。
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来源期刊
Meteorology and Atmospheric Physics
Meteorology and Atmospheric Physics 地学-气象与大气科学
CiteScore
4.00
自引率
5.00%
发文量
87
审稿时长
6-12 weeks
期刊介绍: Meteorology and Atmospheric Physics accepts original research papers for publication following the recommendations of a review panel. The emphasis lies with the following topic areas: - atmospheric dynamics and general circulation; - synoptic meteorology; - weather systems in specific regions, such as the tropics, the polar caps, the oceans; - atmospheric energetics; - numerical modeling and forecasting; - physical and chemical processes in the atmosphere, including radiation, optical effects, electricity, and atmospheric turbulence and transport processes; - mathematical and statistical techniques applied to meteorological data sets Meteorology and Atmospheric Physics discusses physical and chemical processes - in both clear and cloudy atmospheres - including radiation, optical and electrical effects, precipitation and cloud microphysics.
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