UFLUX-GPP: a cost-effective framework for quantifying daily terrestrial ecosystem carbon uptake using satellite data
UFLUX-GPP: a cost-effective framework for quantifying daily terrestrial ecosystem carbon uptake using satellite data
In light of climate change, scaling up in situ eddy covariance (EC) fluxes with Earth observation data has been recognized as a viable strategy for estimating the global terrestrial ecosystem carbon uptake, specifically, gross primary productivity (GPP). Nevertheless, the significant uncertainty in estimation (100–150 PgCyr-1) necessitates the refinement of upscaling algorithms and the use of appropriate satellite data. This technological advancement is particularly sought after in underprivileged regions that are most susceptible to climate crises. Unfortunately, these regions are often constrained by insufficient financial resources and software engineering skills shortages. This study aims to evaluate satellite vegetation proxies [solar-induced fluorescence (SIF); near-infrared reflectance of vegetation (NIRv)] for upscaling GPP and to propose a cost-effective GPP estimation framework called unified FLUXes-GPP (UFLUX-GPP), which can be conveniently operated on a laptop while delivering outstanding performance. The results demonstrated that moderate resolution imaging spectroradiometer (MODIS) NIRv and OCO-2 CSIF exhibited superior performance in the upscaling of EC GPP, with a coefficient of determination ( R2 ) of 0.86 and a root mean square error (RMSE) of 1.55 gCm-2d-1. The integration of multiple satellite-derived vegetation proxies holds the potential to enhance the reliability of the model ( R2=0.89 , RMSE =1.41 gCm-2d-1) with an uncertainty of 8 PgCyr-1, especially in tropical and polar regions. The UFLUX-GPP effectively preserved the ecological responses of GPP to the environment and showed promising potential for predicting future GPP. Although the spatiotemporal density of EC towers may occasionally impede the upscaling performance, UFLUX-GPP can convincingly advance a broader use of satellite remote sensing for GPP estimation.
Zhu, Songyan
122e3311-4c1f-48e9-8aa3-09fcbe990cd9
Xu, Jian
9c28ab96-f012-461e-8e51-e64dc8c8eb02
Zeng, Jingya
55606386-37b9-4c17-a1cc-196eecb77f85
He, Panxing
c9667c4d-848e-4f81-99ef-b6eccac5a505
Wang, Yapeng
78704edb-1c38-4a2b-bac7-a6a4c655b910
Bao, Shanning
cdca527e-b2b7-49e5-b0f6-60f118d7e143
6 August 2024
Zhu, Songyan
122e3311-4c1f-48e9-8aa3-09fcbe990cd9
Xu, Jian
9c28ab96-f012-461e-8e51-e64dc8c8eb02
Zeng, Jingya
55606386-37b9-4c17-a1cc-196eecb77f85
He, Panxing
c9667c4d-848e-4f81-99ef-b6eccac5a505
Wang, Yapeng
78704edb-1c38-4a2b-bac7-a6a4c655b910
Bao, Shanning
cdca527e-b2b7-49e5-b0f6-60f118d7e143
Zhu, Songyan, Xu, Jian, Zeng, Jingya, He, Panxing, Wang, Yapeng and Bao, Shanning
(2024)
UFLUX-GPP: a cost-effective framework for quantifying daily terrestrial ecosystem carbon uptake using satellite data.
IEEE Transactions on Geoscience and Remote Sensing, 62.
(doi:10.1109/TGRS.2024.3439333).
Abstract
In light of climate change, scaling up in situ eddy covariance (EC) fluxes with Earth observation data has been recognized as a viable strategy for estimating the global terrestrial ecosystem carbon uptake, specifically, gross primary productivity (GPP). Nevertheless, the significant uncertainty in estimation (100–150 PgCyr-1) necessitates the refinement of upscaling algorithms and the use of appropriate satellite data. This technological advancement is particularly sought after in underprivileged regions that are most susceptible to climate crises. Unfortunately, these regions are often constrained by insufficient financial resources and software engineering skills shortages. This study aims to evaluate satellite vegetation proxies [solar-induced fluorescence (SIF); near-infrared reflectance of vegetation (NIRv)] for upscaling GPP and to propose a cost-effective GPP estimation framework called unified FLUXes-GPP (UFLUX-GPP), which can be conveniently operated on a laptop while delivering outstanding performance. The results demonstrated that moderate resolution imaging spectroradiometer (MODIS) NIRv and OCO-2 CSIF exhibited superior performance in the upscaling of EC GPP, with a coefficient of determination ( R2 ) of 0.86 and a root mean square error (RMSE) of 1.55 gCm-2d-1. The integration of multiple satellite-derived vegetation proxies holds the potential to enhance the reliability of the model ( R2=0.89 , RMSE =1.41 gCm-2d-1) with an uncertainty of 8 PgCyr-1, especially in tropical and polar regions. The UFLUX-GPP effectively preserved the ecological responses of GPP to the environment and showed promising potential for predicting future GPP. Although the spatiotemporal density of EC towers may occasionally impede the upscaling performance, UFLUX-GPP can convincingly advance a broader use of satellite remote sensing for GPP estimation.
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e-pub ahead of print date: 6 August 2024
Published date: 6 August 2024
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Local EPrints ID: 503492
URI: http://eprints.soton.ac.uk/id/eprint/503492
ISSN: 0196-2892
PURE UUID: 8901ddb7-62b6-42c7-a8a0-74c32e6ff9df
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Date deposited: 04 Aug 2025 16:45
Last modified: 05 Aug 2025 02:13
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Author:
Songyan Zhu
Author:
Jian Xu
Author:
Jingya Zeng
Author:
Panxing He
Author:
Yapeng Wang
Author:
Shanning Bao
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