Publication Details

Category Text Publication
Reference Category Journals
DOI 10.1016/j.csag.2024.100001
Licence creative commons licence
Title (Primary) Coupling of microbial-explicit model and machine learning improves the prediction and turnover process simulation of soil organic carbon
Author Xu, X.; Wang, X.; Zhou, P.; Zhu, Z.; Wei, L.; Wang, S.; Rathinapriya, P.; Bei, Q. ORCID logo ; Feng, J.; Fang, F.; Chen, J.; Ge, T.
Source Titel Climate Smart Agriculture
Year 2024
Department BOOEK
Volume 1
Issue 1
Page From art. 100001
Language englisch
Topic T5 Future Landscapes
Supplements https://ars.els-cdn.com/content/image/1-s2.0-S2950409024000017-mmc1.docx
Keywords Soil organic carbon; Model fusion; Microbial-explicit model; Machine learning; Microbial carbon use efficiency; Bayesian parameter estimation
Abstract Modeling soil organic carbon (SOC) is helpful for understanding its distribution and turnover processes, which can guide the implementation of effective measures for carbon (C) sequestration and enhance land productivity. Process-based simulation with high interpretability and extrapolation, and machine learning modeling with high flexibility are two common methods for investigating SOC distribution and turnover. To take advantage of both methods, we developed a hybrid model by coupling of a two-carbon pool microbial model and machine learning for SOC modeling. Here, we assessed the SOC model's predictive, mapping, and interpretability capabilities for the SOC turnover process on Ningbo region. The results indicate that the microbial model with density-dependence (β = 2) and microbial biomass carbon simulation performed better in modeling the parameters of the microbial-based C cycle, such as microbial carbon use efficiency (CUE), microbial mortality rate, and assimilation rate. By integrating this optimal microbial model and random forest (RF) model, the hybrid model improved the prediction accuracy of SOC, with an increased R2 from 0.74 to 0.84, residual prediction deviation increased from 1.97 to 2.50, and reduced the root-mean-square error from 4.65 to 3.67 g kg−1 compared to the conventional RF model. As a result, the predicted SOC distribution exhibited high spatial variation and provided abundant details. Microbial CUE and potential C input, represented by net primary productivity, emerged as the primary factors driving SOC distribution in Ningbo region. Projections of SOC under the CMIP6 SSP2-4.5 scenario revealed that regional C loss in high SOC areas was mainly caused by decreased microbial CUE and C input, induced by climate change. Our findings highlight the potential of combining the microbial-explicit model and machine learning to improve SOC prediction accuracy and understand SOC feedback in a changing climate.
Persistent UFZ Identifier https://www.ufz.de/index.php?en=20939&ufzPublicationIdentifier=29112
Xu, X., Wang, X., Zhou, P., Zhu, Z., Wei, L., Wang, S., Rathinapriya, P., Bei, Q., Feng, J., Fang, F., Chen, J., Ge, T. (2024):
Coupling of microbial-explicit model and machine learning improves the prediction and turnover process simulation of soil organic carbon
Climate Smart Agriculture 1 (1), art. 100001 10.1016/j.csag.2024.100001