A machine learning model using the snapshot ensemble approach for soil respiration prediction in an experimental Oak Forest

A machine learning model using the snapshot ensemble approach for soil respiration prediction in an experimental Oak Forest

Soil respiration plays a key role in regulating ecosystem CO2 emissions and atmospheric concentrations. However, because it is highly sensitive to the environment and has large temporal and spatial variability, its contribution to the global carbon cycle remains highly uncertain. Recent advances in...

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Bibliographic Details
Main Authors: S.N. Ferdous, J.P. Ahire, R. Bergman, L. Xin, E. Blanc-Betes, Z. Zhang, J. Wang
Format: Article
Language:English
Published: Elsevier 2025-03-01
Series:Ecological Informatics
Subjects:
Biogeochemical model
CO2
Forest ecosystem
ML model
Soil carbon
Online Access:http://www.sciencedirect.com/science/article/pii/S1574954124005338
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Summary:Soil respiration plays a key role in regulating ecosystem CO2 emissions and atmospheric concentrations. However, because it is highly sensitive to the environment and has large temporal and spatial variability, its contribution to the global carbon cycle remains highly uncertain. Recent advances in ecosystem process models have uniquely constrained soil respiration rates, largely based on results from tracing ecosystem CO2 losses using radioisotope and stable isotope methods. However, the computational requirements of process-based models at large scales are costly, limiting their application and prediction capability. To mitigate this requirement for high computational power for the assimilation of high-throughput data to identify patterns and trends in soil respiration and guide in deploying effective strategies to reduce Greenhouse gas (GHG) emission, the application of machine-learning (ML) models can help reduce the requirement of intensive computational capacity and improve the accuracy of predictions. Here, we developed a novel ML model that integrated a hybrid Prophet-ANN and snapshot ensemble approach. First, we extracted temporal features using the Prophet Forecasting model. We then used the Artificial Neural Network (ANN) regression model to correct the forecasting model errors and perform the final prediction using the snapshot ensemble approach. This model can serve as a surrogate for the ForCent model applied to the Oak Ridge National Laboratory deciduous forest. Our proposed model accurately predicted soil CO2 flux for the four studied sites: East Low, West Low, East High, and West High. We show the potential of our proposed ML model to significantly improve soil CO2 flux predictions, which in turn can help us develop more effective strategies for managing soil carbon.
ISSN:1574-9541

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