Forest reorganisation effects on fuel moisture content can exceed changes due to climate warming in wet temperate forests

Brown, Tegan P.; Duff, Thomas J.; Inbar, Assaf; Lane, Patrick N. J.; Sheridan, Gary J.

doi:10.1111/gcb.17023

Global Change Biology

2023

DOI: 10.1111/gcb.17023

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Forest reorganisation effects on fuel moisture content can exceed changes due to climate warming in wet temperate forests

Tegan P. Brown,

Thomas J. Duff,

Assaf Inbar

et al.

Abstract: The distributions of vegetation and fire activity are changing rapidly in response to climate warming. In many regions, climate effects on dead fuel moisture content (FMC) are expected to increase future wildfire activity. However, forest FMC is largely driven by microclimate conditions, which are moderated from open weather by vegetation canopies. As shifts in vegetation increase under climate warming, the extent to which future fire activity will be driven by climate directly or associated vegetation shifts … Show more

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2024

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Cited by 1 publication

References 104 publications

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Prediction of Wildfire Occurrence in the Southern Forest Regions of China in the Future Scenario

Li,

Huang,

Long

et al. 2024

Forests

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In the context of global climate warming, climate change is subtly reshaping the patterns of wildfires. Therefore, it is particularly urgent to conduct in-depth research on climate change, wildfires, and their management strategies. This study relies on detailed fire point data from 2001 to 2020, skillfully incorporating a spatial autocorrelation analysis to uncover the mysteries of spatial heterogeneity, while comprehensively considering the influences of multiple factors such as climate, terrain, vegetation, and socioeconomic conditions. To simulate fire conditions under future climates, we adopted the BCC-CSM2-MR climate model, presetting temperature and precipitation data for two scenarios: a sustainable low-development path and a high-conventional-development path. The core findings of the study include the following: (i) In terms of spatial heterogeneity exploration, global autocorrelation analysis reveals a striking pattern: within the southern forest region, 63 cities exhibiting a low–low correlation are tightly clustered in provinces such as Hubei, Anhui, and Zhejiang, while 48 cities with a high–high correlation are primarily distributed in Guangxi and Guangdong. Local autocorrelation analysis further refines this observation, indicating that 24 high–high correlated cities are highly concentrated in specific areas, 14 low–low correlated cities are located in Hainan, and there are only 3 sparsely distributed cities with a low–high correlation. (ii) During the model construction and validation process, this study innovatively adopted the LR-RF-SVM ensemble model, which demonstrated exceptional performance indicators: an accuracy of 91.97%, an AUC value of 97.09%, an F1 score of 92.13%, a precision of 90.75%, and a recall rate of 93.55%. These figures, significantly outperforming those of the single models SVM and RF, strongly validate the superiority of the ensemble learning approach. (iii) Regarding predictions under future climate scenarios, the research findings indicate that, compared to the current fire situation in southern forest areas, the spatial distribution of wildfires will exhibit a noticeable expansion trend. High-risk regions will not only encompass multiple cities in Hunan, Hubei, southern Anhui, all of Jiangxi, and Zhejiang but will also extend northward into southern forest areas that were previously considered low-risk, suggesting a gradual northward spread of fire risk. Notably, despite the relatively lower fire risk in some areas of Fujian Province under the SS585 scenario, overall, the probability of wildfires occurring in 2090 is slightly higher than that in 2030, further highlighting the persistent intensification of forest fire risk due to climate change.

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Prediction of Wildfire Occurrence in the Southern Forest Regions of China in the Future Scenario

Li,

Huang,

Long

et al. 2024

Forests

View full text Add to dashboard Cite

show abstract

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Forest reorganisation effects on fuel moisture content can exceed changes due to climate warming in wet temperate forests

Cited by 1 publication

References 104 publications

Prediction of Wildfire Occurrence in the Southern Forest Regions of China in the Future Scenario

Prediction of Wildfire Occurrence in the Southern Forest Regions of China in the Future Scenario

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