雷电分布特征与雷击森林火预警

doi:10.11707/j.1001-7488.LYKX20220875

摘要/Abstract

摘要：

闪电引发的野火造成了全球范围内生态、财产和生命的重大损失。随着气候变暖以及厄尔尼诺等现象的出现，全球雷暴和闪电活动显著增加，由其引发的雷击火造成的燃烧面积也显著增加。然而，目前对闪电点火过程和机制的研究还存在很大空白。本文对雷电分布特征、影响雷电密度的因素以及我国雷暴日的规律进行总结归纳，并将其与雷击火的发生和预测相关联，探究闪电规律与雷击火发生之间的关系。闪电的发生，在时间上具有随机性和瞬时性的特点，闪电发生地域不同，其特征也不相同，闪电密度东部比西部高，南部比北部高，陆地比海洋高。森林雷击火是由地闪电流的热效应所导致，引燃与否与闪电的极性、电流强度等特征密切相关。闪电密度还受到海拔、植被分布、土壤类型、地形以及火烧迹地等因素的影响，海拔升高引起强制对流，雷击，林地、灌木和草原由于地表加热程度不同导致雷击密度也不同，而大型火烧迹地通过增强自由对流或中尺度环流引发雷击。受人类活动强烈影响的地区（如城市、采矿区和工业区）的闪电活动更多。从土壤类型来看，冲积土、过渡性红砂土和淋溶土与闪电活动的增加有关。森林大火产生的火积云也可能会引发又一场火灾。我国东经105°以东地区的平均雷暴持续时期随纬度减小而递增。闪电引起雷击火的过程包括放电加热阶段、热反馈阶段和自燃火焰阶段3个阶段，且气候变化会影响闪电的发生和点火概率。在未来，闪电发生次数和着火概率的增加很大程度上会导致空间和时间上火灾风险的增加。目前，闪电预测雷击火模型中往往没有严格评估闪电的发生情况，未来有必要开发一种用于检测闪电长期趋势的系统，通过卫星通信、无人机航拍、利用现有的大气电场测量系统，同时结合人工引雷、野外点火等试验手段，建立雷击火智能化预报模型，以提高我国雷击火发生概率预报的准确度，实现对雷击火的有效防控。

关键词: 雷击火, 雷暴日, 云地闪, 点火机制, 气候变化

Abstract:

Wildfires triggered by lightning have caused significant losses of ecology, property and life worldwide. With climate warming and El Nino phenomena, there has been a significant increase in the activity of thunderstorms and lightning around the world, and the area burned by lightning-caused fires has increased significantly. However, at present, there is still a big knowledge gap in the research on the lightning ignition process and mechanism. In this paper, we summarized the rule of lightning, factors affecting lightning density and the pattern of lightning days in China, made a link between the occurrence and prediction of lightning-caused fires, and explored the relationship between the pattern of lightning and lightning-caused fires. The lightning occurrence has the characteristics of randomness and instantaneity in time, and the characteristics of lightning are different in different regions. The lightning density is higher in the east than in the west, in the south than in the north, and on the land than in the sea. Lightning-caused fires in the forest are caused by the thermal effect of cloud-ground lightning current. Ignition or not is closely related to the polarity and current intensity of lightning. Lightning density is also affected by altitude, vegetation distribution, soil type, topography and burned area. Higher elevations cause forced convection, which leads to lightning strikes. Woodland, shrub and grassland have different lightning strike densities due to different surface heating levels. Large burned areas cause lightning strikes through enhanced free convection or mesoscale circulation; and the areas strongly influenced by human activities (such as urban, mining, and industrial) have more lightning activity. Fluvisols, cambic-arenosols and luvisols are associated with increased lightning activity. The cumulus clouds generated by forest fires may also trigger another fire. The mean thunderstorm duration in the region east of 105°E increases with decreasing latitude. The process of lightning-induced lightning fires includes three stages: discharge heating stage, thermal feedback stage and spontaneous flame stage. Moreover, climate change can affect the occurrence and ignition probability of lightning. In the future, the increase of lightning occurrence and ignition probability will largely lead to the increase of fire risk in space and time. At present, lightning prediction models often do not rigorously assess the occurrence of lightning. Measurement systems to detect long-term trends in lightning should be developed in the future. By means of satellite communication, UAV, atmospheric electric field measuring system, combined with artificially triggered lightning technique and field ignition experiment, the intelligent forecast models of lightning-caused fires should be established to improve the accuracy of the probability forecast of lightning-caused fires in China, and realize the effective prevention and control of lightning-caused fires.

Key words: lightning-caused fire, thunderstorm day, cloud-to-ground lightning, ignition mechanism, climate change

中图分类号:

S762

司莉青,王明玉,陈锋,舒立福,赵凤君,李伟克. 雷电分布特征与雷击森林火预警[J]. 林业科学, 2023, 59(10): 1-8.

Liqing Si,Mingyu Wang,Feng Chen,Lifu Shu,Fengjun Zhao,Weike Li. Distribution Characteristics of Lightning and the Warning of Lightning-Caused Forest Fires[J]. Scientia Silvae Sinicae, 2023, 59(10): 1-8.

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