Optimising future scenarios of forest fire occurrence in Daxing'anling using long-term survey data and intelligent modelling

IF 5.2 1区地球科学 Q1 ENVIRONMENTAL SCIENCES

Advances in Climate Change Research Pub Date : 2026-04-01 Epub Date: 2026-01-22 DOI:10.1016/j.accre.2026.01.004

Ya-Kui Shao , Wei-Ke Li , Ming-Yu Wang , Qiu-Yang Du , Jia Wang , Li-Fu Shu , Li-Qing Si , Feng-Jun Zhao , Zhong-Ke Feng , Lin-Hao Sun , Xu-Sheng Li , Ai-Ai Wang , Zi-Xuan Qiu , Zhi-Chao Wang

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引用次数: 0

Abstract

The Daxing'anling Mountains, as a climate-sensitive region, are experiencing forest fires that threaten the area's ecological security. Nevertheless, most of the existing fire prediction models are stationary. They do not have an all-embracing scheme for simultaneously managing fire ignition causes, dynamic fire scenarios and spatial targeting. Hence, the development of an accurate and efficient forest fire forecasting system is vital. This study establishes a prediction framework that integrates long-term survey data with multi-source remote sensing, incorporating spatiotemporal clustering, spatial autocorrelation and an optimised ensemble of LR–RF–SVM–GBDT algorithms. Among the 3368 recorded fire incidents, lightning-ignited fires accounted for 51.19%, making lightning storms the predominant cause of ignition. While the frequency of lightning-induced fires increased significantly (1.24 per year, p < 0.05), the total burned area remained relatively stable. The proposed framework outperformed individual models by achieving higher predictive metrics (accuracy = 0.89, AUC = 0.94, F1 = 0.89) and providing robust support for operational early warning and real-time management. The projections for future climate, based on the SSP126 and SSP585 scenarios, depict a notable geographical shift in fire-prone areas. Besides the traditionally known eastern areas of Xiaogenhe and Chabanhe, which are expected to see an increase in fire occurrences, new high-fire-risk areas are expected to emerge in the central–western regions, such as Huzhong and Wuyuan. Quantitative findings reveal that the divergence in forest fire probabilities between the high-emission SSP585 and SSP126 scenarios will increase over time. The expected increase ranges from 0.29% in the 2030s to 0.92% in the 2050s, then rises to 4.48% in the 2070s and reaches 6.48% by the 2090s. These figures highlight the urgency of implementing fire management practices that are not only adaptive but also specific to particular areas. The scenario-based forecasts represent a proactive approach to assisting forest fire governance under climate change, providing a basis for future decisions as quantitative evidence.

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基于长期调查数据和智能建模的大兴安岭森林火灾未来情景优化

大兴安岭作为一个气候敏感地区，正在经历威胁该地区生态安全的森林火灾。然而，大多数现有的火灾预测模型是平稳的。他们没有一个包罗万象的方案来同时管理起火原因、动态火灾场景和空间瞄准。因此，开发一个准确、高效的森林火灾预报系统至关重要。本研究建立了一个将长期调查数据与多源遥感相结合，结合时空聚类、空间自相关和LR-RF-SVM-GBDT算法优化集成的预测框架。在记录在案的3368起火灾中，闪电引燃的火灾占51.19%，雷暴是主要的引燃原因。雷击火灾发生频率显著增加（1.24次/年，p < 0.05），但总烧毁面积保持相对稳定。该框架通过实现更高的预测指标（准确率= 0.89,AUC = 0.94, F1 = 0.89），并为作战预警和实时管理提供强大的支持，从而优于单个模型。基于SSP126和SSP585情景的未来气候预估描绘了火灾易发地区的显著地理变化。除了传统上已知的东部小根河和茶板河地区的火灾发生率预计会增加外，中西部地区预计会出现新的高火灾风险地区，如湖中和婺源。定量结果表明，高排放情景SSP585和SSP126的森林火灾概率差异将随着时间的推移而增大。预计增长范围从本世纪30年代的0.29%到本世纪50年代的0.92%，然后在本世纪70年代上升到4.48%，到本世纪90年代达到6.48%。这些数字突出了实施消防管理实践的紧迫性，这些实践不仅具有适应性，而且针对特定地区。基于情景的预测代表了一种协助气候变化下森林火灾治理的主动方法，作为定量证据为未来决策提供了基础。

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来源期刊

Advances in Climate Change Research Earth and Planetary Sciences-Atmospheric Science

CiteScore

9.80

自引率

4.10%

发文量

424

审稿时长

107 days

期刊介绍： Advances in Climate Change Research publishes scientific research and analyses on climate change and the interactions of climate change with society. This journal encompasses basic science and economic, social, and policy research, including studies on mitigation and adaptation to climate change. Advances in Climate Change Research attempts to promote research in climate change and provide an impetus for the application of research achievements in numerous aspects, such as socioeconomic sustainable development, responses to the adaptation and mitigation of climate change, diplomatic negotiations of climate and environment policies, and the protection and exploitation of natural resources.