Enhancing mountainous permafrost mapping by leveraging a rock glacier inventory in northeastern Tibetan Plateau

ABSTRACTOur understanding of permafrost distribution is still limited, particularly in mountainous areas where highly heterogeneous environments and a lack of reliable field data tend to prevail. The extensive distribution of rock glaciers in the Qilian Mountains, located in the northeastern Tibetan...

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Bibliographic Details
Published in:International Journal of Digital Earth
Main Authors: Zhongyi Hu, Dezhao Yan, Min Feng, Jinhao Xu, Sihai Liang, Yu Sheng
Format: Article in Journal/Newspaper
Language:English
Published: Taylor & Francis Group 2024
Subjects:
Mountainous permafrost
rock glacier
northeastern Tibetan Plateau
machine learning
Mathematical geography. Cartography
GA1-1776
permafrost
Online Access:https://doi.org/10.1080/17538947.2024.2304077
https://doaj.org/article/da8599eed69f48609617176c0333e039
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Summary:ABSTRACTOur understanding of permafrost distribution is still limited, particularly in mountainous areas where highly heterogeneous environments and a lack of reliable field data tend to prevail. The extensive distribution of rock glaciers in the Qilian Mountains, located in the northeastern Tibetan Plateau, offers the opportunity to develop a novel approach for permafrost mapping in mountainous regions. In this study, a total of 1,530 rock glacier records were combined with in situ data to drive machine learning models for estimating permafrost presence. Three machine learning algorithms were adopted, and their accuracies were assessed in both mountains and plains by comparing the mapped permafrost to reserved field data as well as other published permafrost datasets. Among the algorithms tested, the CatBoost model presented the highest accuracy, with an overall accuracy of 83.3%. The model was thus chosen to produce a 250-m resolution permafrost zonation index (PZI) map, which identified a total area of 73.1 × 103 km2 permafrost in the Qilian Mountains, accounting for 39.1% of the area. The map also presented higher accuracy than other published permafrost maps. This study demonstrated that rock glacier records coupled with gradient-boosting machine-learning algorithms can help improve permafrost mapping, especially in the most challenging mountainous permafrost areas.

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