Abstract
Remotely sensed data from both in situ and satellite platforms in visible, near-infrared, and shortwave infrared (VNIR–SWIR, 400–2500 nm) regions have been widely used to characterize and model soil properties in a direct, cost-effective, and rapid manner at different scales. In this study, we assess the performance of machine-learning algorithms including random forest (RF), extreme gradient boosting machines (XGBoost), and support vector machines (SVM) to model salt marsh soil bulk density using multispectral remote-sensing data from the Landsat-7 Enhanced Thematic Mapper Plus (ETM+) platform. To our knowledge, use of remote-sensing data for estimating salt marsh soil bulk density at the vegetation rooting zone has not been investigated before. Our study reveals that blue (band 1; 450–520 nm) and NIR (band 4; 770–900 nm) bands of Landsat-7 ETM+ ranked as the most important spectral features for bulk density prediction by XGBoost and RF, respectively. According to XGBoost, band 1 and band 4 had relative importance of around 41% and 39%, respectively. We tested two soil bulk density classes in order to differentiate salt marshes in terms of their capability to support vegetation that grows in either low (0.032 to 0.752 g/cm3) or high (0.752 g/cm3 to 1.893 g/cm3) bulk density areas. XGBoost produced a higher classification accuracy (88%) compared to RF (87%) and SVM (86%), although discrepancies in accuracy between these models were small (<2%). XGBoost correctly classified 178 out of 186 soil samples labeled as low bulk density and 37 out of 62 soil samples labeled as high bulk density. We conclude that remote-sensing-based machine-learning models can be a valuable tool for ecologists and engineers to map the soil bulk density in wetlands to select suitable sites for effective restoration and successful re-establishment practices.
Highlights
Salt marshes are ecologically sensitive ecosystems that connect the terrestrial and marine environments and serve as critical habitats for flora and fauna [1,2,3,4,5,6,7]
The main objective of this study is to evaluate the capability of freely accessible multispectral Landsat-7 data for estimating salt marsh soil bulk density by comparing the performance of random forest (RF), super vector machine (SVM), and extreme gradient boosting (XGBoost) models and rank the most important spectral bands for bulk density estimation
Machine-learning algorithms and Landsat-7 (ETM+) spectral bands were used in this study to model salt marsh soil bulk density
Summary
Salt marshes are ecologically sensitive ecosystems that connect the terrestrial and marine environments and serve as critical habitats for flora and fauna [1,2,3,4,5,6,7]. Disturbances cause irreversible alterations in the condition of salt marsh communities over time [10,11,12,13,14,15]. An increase in soil bulk density changes the soil aeration properties [28], alters soil biological processes due to a decrease in soil temperature [29], expedites the soil denitrification process [30], causes loss in the mycorrhizal fungi community [31], and restricts the vegetation root growth [32]. Bulk density reflects soil’s structural stability to support vegetation growth against the destructive impacts of tidal flooding; bulk density greater than 1.6 g/cm is not suitable for root and plant growth in salt marshes [34]. Studies have shown that an increase in soil bulk density from 1.1 to 1.4 g/cm yielded a 42% reduction in oxygen diffusion rate through waterlogged salt marsh soil, while the induced changes in soil bulk density from
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