A harmonized global gridded transpiration product based on collocation analysis

Transpiration (T) is pivotal in the global water cycle, responding to soil moisture, atmospheric stress, climate changes, and human impacts. Therefore, establishing a reliable global transpiration dataset is essential. Collocation analysis methods have been proven effective for assessing the errors...

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Bibliographic Details
Published in:Scientific data 2024-06, Vol.11 (1), p.604-21
Main Authors: Li, Changming, Han, Juntai, Liu, Ziwei, Tu, Zhuoyi, Yang, Hanbo
Format: Article
Language:English
Subjects:
704/106/242
704/242
Climate Change
Data Descriptor
Datasets
Humanities and Social Sciences
Hydrologic cycle
multidisciplinary
Plant Transpiration
Science
Science (multidisciplinary)
Soil
Soil moisture
Transpiration
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Summary:Transpiration (T) is pivotal in the global water cycle, responding to soil moisture, atmospheric stress, climate changes, and human impacts. Therefore, establishing a reliable global transpiration dataset is essential. Collocation analysis methods have been proven effective for assessing the errors in these products, which can subsequently be used for multisource fusion. However, previous results did not consider error cross-correlation, rendering the results less reliable. In this study, we employ collocation analysis, taking error cross-correlation into account, to effectively analyze the errors in multiple transpiration products and merge them to obtain a more reliable dataset. The results demonstrate its superior reliability. The outcome is a long-term daily global transpiration dataset at 0.1°from 2000 to 2020. Using the transpiration after partitioning at FLUXNET sites as a reference, we compare the performance of the merged product with inputs. The merged dataset performs well across various vegetation types and is validated against in-situ observations. Incorporating non-zero ECC considerations represents a significant theoretical and proven enhancement over previous methodologies that neglected such conditions, highlighting its reliability in enhancing our understanding of transpiration dynamics in a changing world.
ISSN:2052-4463
2052-4463
DOI:10.1038/s41597-024-03425-7