Abstract
Accurate monitoring of plant dust retention can provide a basis for dust pollution control and environmental protection. The aims of this study were to analyze the spectral response features of grassland plants to mining dust and to predict the spatial distribution of dust retention using hyperspectral data. The dust retention content was determined by an electronic analytical balance and a leaf area meter. The leaf reflectance spectrum was measured by a handheld hyperspectral camera, and the airborne hyperspectral data were obtained using an imaging spectrometer. We analyzed the difference between the leaf spectral before and after dust removal. The sensitive spectra of dust retention on the leaf- and the canopy-scale were determined through two-dimensional correlation spectroscopy (2DCOS). The competitive adaptive reweighted sampling (CARS) algorithm was applied to select the feature bands of canopy dust retention. The estimation model of canopy dust retention was built through random forest regression (RFR), and the dust distribution map was obtained based on the airborne hyperspectral image. The results showed that dust retention enhanced the spectral reflectance of leaves in the visible wavelength but weakened the reflectance in the near-infrared wavelength. Caused by the canopy structure and multiple scattering, a slight difference in the sensitive spectra on dust retention existed between the canopy and leaves. Similarly, the sensitive spectra of leaves and the canopy were closely related to dust and plant physiological parameters. The estimation model constructed through 2DCOS-CARS-RFR showed higher precision, compared with genetic algorithm-random forest regression (GA-RFR) and simulated annealing algorithm-random forest regression (SAA-RFR). Spatially, the amount of canopy dust increased and then decreased with increasing distance from the mining area, reaching a maximum within 300–500 m. This study not only demonstrated the importance of extracting feature bands based on the response of plant physical and chemical parameters to dust, but also laid a foundation for the rapid and non-destructive monitoring of grassland plant dust retention.
Highlights
Mineral coal is the second most widely used fossil fuel in the world and the first in terms of reserves for future use [1]
Compared with general atmospheric dust pollution, mining dust has the following characteristics [4,8]: (1) dust pollution is centered on mining pits, coal yards, and transportation trunk lines; (2) the dust diffusion distance is relatively short, and its aggregation feature is obvious; (3) the size of most mining dust particles is greater than 10 μm; and (4) mining dust contains a certain amount of heavy metals
The dust retention content varies from 0.353–51.425 g/m2 of Leymus chinensis, 1.813–52.810 g/m2 of Cleistogenes squarrosa, 2.441–62.064 g/m2 of Potentilla acaulis, 0.532–47.312 g/m2 of Scutellaria scordifolia, and 1.486–54.688 g/m2 of the canopy
Summary
Mineral coal is the second most widely used fossil fuel in the world and the first in terms of reserves for future use [1]. Coal mining enhances the development of the world economy. The mining, loading, unloading, and transportation of open-pit coal mines cause large amounts of fugitive dust. Compared with general atmospheric dust pollution, mining dust has the following characteristics [4,8]: (1) dust pollution is centered on mining pits, coal yards, and transportation trunk lines; (2) the dust diffusion distance is relatively short, and its aggregation feature is obvious; (3) the size of most mining dust particles is greater than 10 μm; and (4) mining dust contains a certain amount of heavy metals
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