LTER Publications - Zou, H., et.al. 2025. Contributions of vegetation heterogeneity within tower footprint to CO2 flux estimations through graph neural network modeling. Remote Sensing of Environment 329:114952.

Zou, H., J. Chen, X. Li, J. Zhu, X. Liu, Z. Tian, Z. Chen, J. Dai, Z. Xue, and G. P. Robertson. 2025. Contributions of vegetation heterogeneity within tower footprint to CO2 flux estimations through graph neural network modeling. Remote Sensing of Environment 329:114952.

Citable PDF link: https://lter.kbs.msu.edu/pub/4244

Net ecosystem exchange of CO₂ (Fc) measured directly by eddy covariance towers is based on various assumptions, including large, flat and homogenous land cover type. In reality, often a tower site is not large enough for flux measurements, and landscapes consist of patches of different land cover types within the flux footprint. In addition, some portions of fluxes are contributed by different cover types when a footprint exceeds the size of the target ecosystem. The contributions of non-dominant patches to Fc are often ignored. In this study, we propose a novel integrated modeling framework that combines random forest (RF) and XGBoost with a residual correction module based on a deep graph convolutional network (DeeperGCN) to simulate Fc for seven flux measurement sites in southwest Michigan. High-resolution remote sensing vegetation indices, soil properties, meteorological variables, and footprint-weighted spatial features were used as model inputs at three spatial resolutions (10 m, 20 m, 30 m), and their importance in predicting Fc with DeeperGCN was assessed. We found that residual correction using DeeperGCN significantly improved prediction accuracy, with the R2 increasing from 0.9098 to 0.9479 for RF and from 0.9235 to 0.9433 for XGBoost. At site level, the maximum improvement in R2 reached 0.1617. Paired t-tests confirmed that these improvements were statistically significant (p < 0.05). Among all predictors, leaf area index and incoming shortwave radiation emerged as the dominant drivers of spatial residual variation, followed by precipitation, relative humidity, and selected vegetation indices. The 20 m resolution yielded the best balance between model performance and computational efficiency. Our modeling framework effectively captures both spatial heterogeneity and nonlinear interactions, offering a robust solution for spatially explicit flux modeling in structurally diverse ecosystems beyond the study sites.

DOI: 10.1016/j.rse.2025.114952

Associated Treatment Areas:

M1 CRP-Corn
M2 CRP-Prairie
M3 CRP-Switchgrass
M4 CRP-Reference
L1 AGR-Corn
L2 AGR-Switchgrass
L3 AGR-Prairie
GLBRC Research Context

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