Abstract
Soil organic carbon (SOC) is an important soil property that has profound impact on soil quality and plant growth. With 140 soil samples collected from Ebinur Lake Wetland National Nature Reserve, Xinjiang Uyghur Autonomous Region of China, this research evaluated the feasibility of visible/near infrared (VIS/NIR) spectroscopy data (350–2,500 nm) and simulated EO-1 Hyperion data to estimate SOC in arid wetland regions. Three machine learning algorithms including Ant Colony Optimization-interval Partial Least Squares (ACO-iPLS), Recursive Feature Elimination-Support Vector Machine (RF-SVM), and Random Forest (RF) were employed to select spectral features and further estimate SOC. Results indicated that the feature wavelengths pertaining to SOC were mainly within the ranges of 745–910 nm and 1,911–2,254 nm. The combination of RF-SVM and first derivative pre-processing produced the highest estimation accuracy with the optimal values of Rt (correlation coefficient of testing set), RMSEt and RPD of 0.91, 0.27% and 2.41, respectively. The simulated EO-1 Hyperion data combined with Support Vector Machine (SVM) based recursive feature elimination algorithm produced the most accurate estimate of SOC content. For the testing set, Rt was 0.79, RMSEt was 0.19%, and RPD was 1.61. This practice provides an efficient, low-cost approach with potentially high accuracy to estimate SOC contents and hence supports better management and protection strategies for desert wetland ecosystems.
Highlights
Wetlands account for a significant portion of global carbon stocks (Hu et al, 2010)
The ant colony optimization (ACO)-interval partial least squares (iPLS) algorithm first selected the informative spectra segments, and relevant spectra segments were entered to the model to predict the Soil organic carbon (SOC) content
This study clearly suggests that visible/near infrared (VIS/NIR) spectroscopy is an effective method to detect wetland SOC content of soils in arid regions
Summary
Wetlands account for a significant portion of global carbon stocks (Hu et al, 2010). According to the United Nations Environment Programme’s (UNEP) World Conservation Monitoring Centre, the total area of wetlands is about 6% of the total land area globally. Carbon stocks within the wetlands accounts for 14% of the entire land ecosystems How to cite this article Ding et al (2018), Machine-learning-based quantitative estimation of soil organic carbon content by VIS/NIR spectroscopy. Due to its high carbon storage, any slight change in wetland carbon stocks might result in significant effect on global climate change (Wang, Zhang & Haimiti, 2015). Changes in wetland carbon stocks can increase carbon dioxide concentration and methane in the atmosphere, which might lead to more severe global warming (Pott & Pott, 2004)
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