New data‐driven method for estimation of net ecosystem carbon exchange at meteorological stations effectively increases the global carbon flux data

Zhang, Wenqiang; Luo, Geping; Yuan, Xiuliang; Li, Chaofan; Xie, Mingjuan; Wang, Yuangang; Ma, Xiaofei; Shi, Haiyang; Hamdi, Rafiq; Hellwich, Olaf; Ma, Xiumei; Termonia, Piet; Maeyer, Philippe De

doi:10.1111/2041-210x.14188

Cited by 6 publications

(2 citation statements)

References 46 publications

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“…The RF model is considered a reasonable and suitable method for simulating CO 2 fluxes from site to regional scales. Firstly, as a machine learning algorithm, the RF model selects the optimal output from multiple regression trees to capture the features of the data, effectively enhancing the accuracy of flux data [56,57]. Secondly, by extracting the multivariate functional relationships between observed data and explanatory variables, the RF model can integrate data from different sources and simplify complex processes, addressing nonlinear issues in ecosystems [58].…”

Section: Discussionmentioning

confidence: 99%

Spatiotemporal Modeling of Carbon Fluxes over Complex Underlying Surfaces along the North Shore of Hangzhou Bay

Zhang,

Zhao,

Zhao

et al. 2024

Atmosphere

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Urban areas contribute to over 80% of carbon dioxide emissions, and considerable efforts are being undertaken to characterize spatiotemporal variations of CO2 (carbon dioxide) at a city, regional, and national level, aiming at providing pipelines for carbon mission reduction. The complex underlying surface composition of urban areas makes process-based and physiology-based models inadequate for simulating carbon flux in this context. In this study, long short-term memory (LSTM), support vector machine (SVM), random forest (RF), and artificial neural network (ANN) were employed to develop and investigate their viability in estimating carbon flux at the ecosystem level. All the data used in our study were derived from the long-term chronosequence observations collected from the flux towers within urban complex underlying surface, along with meteorological reanalysis datasets. To assess the generalization ability of these models, the following statistical metrics were utilized: coefficient of determination (R2), root mean square error (RMSE), and mean absolute error (MAE). Our analysis revealed that the RF model performed the best in simulating carbon flux over long time series, with the highest R2 values reaching up to 0.852, and exhibiting the smallest RMSE and MAE values at 0.293 μmol·m−2·s−1 and 0.157 μmol·m−2·s−1. As a result, the RF model was chosen for simulating carbon flux at spatial scale and assessing the impact of urban impervious surfaces in the simulation. The results showed that the RF model performs well in simulating carbon flux at the spatial scale. The input of impervious surface area index can improve the performance of the RF model in simulating carbon flux, with R2 values of 84.46% (with the impervious surface area index in) and 83.74% (without the impervious surface area index in). Furthermore, the carbon flux in Fengxian District, Shanghai, exhibited significant spatial heterogeneity: the CO2 flux in the western part of Fengxian District was less than in the eastern part, and the CO2 flux gradually increased from the west to the east. In addition, we creatively introduced the diurnal impervious surface area index based on the Kljun model, and clarified the influence of impervious surface on the spatiotemporal simulation of CO2 flux over the complex urban underlying surface. Based on these findings, we conclude that the RF models can be effectively applied for estimating carbon flux on the complex underlying urban surface. The results of our study reduce the uncertainty in modeling carbon cycling in terrestrial ecosystems, and make the variety of models for the carbon cycling of terrestrial ecosystems more diverse.

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Section: Discussionmentioning

confidence: 99%

Spatiotemporal Modeling of Carbon Fluxes over Complex Underlying Surfaces along the North Shore of Hangzhou Bay

Zhang,

Zhao,

Zhao

et al. 2024

Atmosphere

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“…Interestingly, in ecological dynamics of net ecosystem exchange (NEE), Kong et al (2022) expressed that NEE's interactions with other environmental variables remained a challenging task for the reasons that the latter varies across ecosystems and climate regimes. In Zhang et al (2023), the inclusion of NEE was observed to improve the terrestrial photosynthesis model and global carbon cycle prediction amidst climate changes. The same assertion was shown by Mahmud et al (2021) for dryland global carbon cycle contribution using the global terrestrial biosphere model including those predicted for urban forests 22,23 , peatland mosses 24 , tropical vegetation 25 , as well as environmental processes of soil respirations ?,27 and land-ocean-atmosphere carbon exchange 28,29,30 .…”

Section: Introductionmentioning

confidence: 99%

Universality of ecological memory for local and global net ecosystem exchange, atmospheric CO2, and sea surface temperature

ELNAR,

Bernido

2024

Preprint

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Modeling global net ecosystem exchange is essential to understanding and quantifying the complex interactions between the Earth’s terrestrial ecosystems and the atmosphere. Emphasizing the interrelatedness between the global net ecosystem exchange, global sea surface temperature, and atmospheric CO2 levels, intuitively suggests that all three systems may exhibit collective environmental memory. Motivated by this, we explicitly identified a collective memory function and showed a similar non-Markovian stochastic behavior for these systems exhibiting superdiffusive behavior in short time intervals. These results were consistent with our previous analyses at the ecosystem level suggesting scale invariance for these phenomena. Thus, the observed superdif fusive behavior operating at different scales suggests the universality of the collective memory function for these systems.

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Drought changes the dominant water stress on the grassland and forest production in the northern hemisphere

Zhang,

Luo,

Hamdi

et al. 2024

Agricultural and Forest Meteorology

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New data‐driven method for estimation of net ecosystem carbon exchange at meteorological stations effectively increases the global carbon flux data

Cited by 6 publications

References 46 publications

Spatiotemporal Modeling of Carbon Fluxes over Complex Underlying Surfaces along the North Shore of Hangzhou Bay

Spatiotemporal Modeling of Carbon Fluxes over Complex Underlying Surfaces along the North Shore of Hangzhou Bay

Universality of ecological memory for local and global net ecosystem exchange, atmospheric CO2, and sea surface temperature

Drought changes the dominant water stress on the grassland and forest production in the northern hemisphere

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