UFLUX v2.0: a process-informed machine learning framework for efficient and explainable modelling of terrestrial carbon uptake
UFLUX v2.0: a process-informed machine learning framework for efficient and explainable modelling of terrestrial carbon uptake
Gross Primary Productivity (GPP), the amount of carbon plants fixed by photosynthesis, is pivotal for understanding the global carbon cycle and ecosystem functioning. Processbased models built on the knowledge of ecological processes, are susceptible to biases stemming from their assumptions and approximations. These limitations potentially result in considerable uncertainties in global GPP estimation, which may pose significant challenges to our Net Zero goals. This study presents UFLUX v2.0, a process-informed model that integrates state-of-the-art ecological knowledge and advanced machine learning technique to reduce uncertainties in GPP estimation by learning the biases between process-based models and eddy covariance (EC) measurements. In our findings, UFLUX v2.0 demonstrated a substantial improvement in model accuracy, achieving an R2 of 0.79 with a reduced RMSE of 1.60 gCm-2 d-1, compared to the process-based model's R2 of 0.51 and RMSE of 3.09 gCm-2 d-1. Our global GPP distribution analysis indicates that while UFLUX v2.0 and the process-based model achieved similar global total GPP (137.47 PgC and 132.23 Pg C, respectively), they exhibited large differences in spatial distribution, particularly in latitudinal gradients. These differences are very likely due to systematic biases in the process-based model and differing sensitivities to climate and environmental conditions. This study offers improved adaptability for GPP modelling across diverse ecosystems, and further enhances our understanding of global carbon cycles and its responses to environmental changes.
Carbon uptake, GPP, bias correction, flux upscaling, terrestrial ecosystems, Bias correction, gross primary productivity (GPP), carbon uptake
Dong, Wenquan
8009e9c7-00e7-44cf-b694-60d7731ce1cf
Zhu, Songyan
122e3311-4c1f-48e9-8aa3-09fcbe990cd9
Xu, Jian
6e106854-83a8-4c26-8880-5bfa9b6b0717
Ryan, Casey m.
e8394787-f0ed-4972-8812-6704d72e398b
Chen, Man
4566471c-3d64-494c-8958-a9758245e8c5
Zeng, Jingya
0c065714-6556-48a3-9766-bb416ce67eec
Yu, Hao
4512a5d2-20f6-4f00-b8c9-d397a9d813aa
Cao, Congfeng
be517b39-4e64-4f9f-a20b-c87c69e198dc
Shi, Jiancheng
e134ec40-6feb-4cd2-ba08-481b6385ba85
Dong, Wenquan
8009e9c7-00e7-44cf-b694-60d7731ce1cf
Zhu, Songyan
122e3311-4c1f-48e9-8aa3-09fcbe990cd9
Xu, Jian
6e106854-83a8-4c26-8880-5bfa9b6b0717
Ryan, Casey m.
e8394787-f0ed-4972-8812-6704d72e398b
Chen, Man
4566471c-3d64-494c-8958-a9758245e8c5
Zeng, Jingya
0c065714-6556-48a3-9766-bb416ce67eec
Yu, Hao
4512a5d2-20f6-4f00-b8c9-d397a9d813aa
Cao, Congfeng
be517b39-4e64-4f9f-a20b-c87c69e198dc
Shi, Jiancheng
e134ec40-6feb-4cd2-ba08-481b6385ba85
Dong, Wenquan, Zhu, Songyan, Xu, Jian, Ryan, Casey m., Chen, Man, Zeng, Jingya, Yu, Hao, Cao, Congfeng and Shi, Jiancheng
(2025)
UFLUX v2.0: a process-informed machine learning framework for efficient and explainable modelling of terrestrial carbon uptake.
IEEE Geoscience and Remote Sensing Letters, 22, [2503505].
(doi:10.1109/LGRS.2025.3541893).
Abstract
Gross Primary Productivity (GPP), the amount of carbon plants fixed by photosynthesis, is pivotal for understanding the global carbon cycle and ecosystem functioning. Processbased models built on the knowledge of ecological processes, are susceptible to biases stemming from their assumptions and approximations. These limitations potentially result in considerable uncertainties in global GPP estimation, which may pose significant challenges to our Net Zero goals. This study presents UFLUX v2.0, a process-informed model that integrates state-of-the-art ecological knowledge and advanced machine learning technique to reduce uncertainties in GPP estimation by learning the biases between process-based models and eddy covariance (EC) measurements. In our findings, UFLUX v2.0 demonstrated a substantial improvement in model accuracy, achieving an R2 of 0.79 with a reduced RMSE of 1.60 gCm-2 d-1, compared to the process-based model's R2 of 0.51 and RMSE of 3.09 gCm-2 d-1. Our global GPP distribution analysis indicates that while UFLUX v2.0 and the process-based model achieved similar global total GPP (137.47 PgC and 132.23 Pg C, respectively), they exhibited large differences in spatial distribution, particularly in latitudinal gradients. These differences are very likely due to systematic biases in the process-based model and differing sensitivities to climate and environmental conditions. This study offers improved adaptability for GPP modelling across diverse ecosystems, and further enhances our understanding of global carbon cycles and its responses to environmental changes.
Text
UFLUX2
- Accepted Manuscript
More information
Accepted/In Press date: 2025
e-pub ahead of print date: 28 February 2025
Keywords:
Carbon uptake, GPP, bias correction, flux upscaling, terrestrial ecosystems, Bias correction, gross primary productivity (GPP), carbon uptake
Identifiers
Local EPrints ID: 500575
URI: http://eprints.soton.ac.uk/id/eprint/500575
ISSN: 1545-598X
PURE UUID: ca31eefe-37f4-464c-b1a9-eefbc655702b
Catalogue record
Date deposited: 06 May 2025 16:51
Last modified: 28 Aug 2025 02:30
Export record
Altmetrics
Contributors
Author:
Wenquan Dong
Author:
Songyan Zhu
Author:
Jian Xu
Author:
Casey m. Ryan
Author:
Man Chen
Author:
Jingya Zeng
Author:
Hao Yu
Author:
Congfeng Cao
Author:
Jiancheng Shi
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics