Soil Cd Content Retrieval from Hyperspectral Remote Sensing Data Based on Organic Matter Characteristic Spectral Bands

To address the mechanistic limitations and data redundancy issues in the quantitative retrieval of soil Cd using hyperspectral remote sensing, an inversion method was proposed based on organic matter characteristic spectral bands. The method involved the extraction of characteristic spectral bands of organic matter with adsorption effects on heavy metal Cd in soil spectra. Subsequently, competitive adaptive reweighted sampling (CARS) was employed to optimize the selected spectral bands, and a partial least squares regression (PLSR) model was developed for the inversion of heavy metal Cd. The proposed method was validated by using laboratory spectral data from the Chenzhou mine and field spectral data from the Hami Huangshan South mine. The results demonstrated that the extraction of organic matter characteristic spectral bands not only reduced data redundancy but also significantly improved the accuracy of Cd inversion. In comparison to the correlation coefficient (CC) and genetic algorithm (GA) methods, the CARS algorithm exhibited superior performance in feature selection and inversion accuracy. The validation accuracies, expressed as R2, were 0.94 for the Chenzhou laboratory spectral data and 0.80 for the Hami field spectral data, indicating the robustness of the CARS-PLSR algorithm for both laboratory and field spectra. The findings can provide valuable references for feature band selection and algorithm optimization in the hyperspectral estimation of soil heavy metal content. The proposed method effectively addressed the limitations of existing approaches by leveraging the unique spectral characteristics of organic matter in soil.

Keywords: hyperspectral remote sensing, soil heavy metal, soil spectrally active substance, feature selection, retrieval

 

GMOCHOWSKA W,PIETRANIK A,TYSZKA R,et al. Sources of pollution and distribution of Pb, Cd and Hg in Wroclaw soils; insight from chemical and Pb isotope composition [ J ]. Geochemistry, 2019, 79(3) ;434 -445.

WANG X В ,LI X Y, YAN X,et al. Environmental risks for application of iron and steel slags in soils in China: a review [J]. Pedosphere ,2021 ,31(1): 28 -42.

YU Haiyang,XIE Saifei,GUO Linghui,et al. Extremely randomized trees estimation of soil heavy metal content by fusing spectra and spatial features[J]. Transactions of the Chinese Society for Agricultural Machinery ,2022, 53(8) *.231 -239. (in Chinese)

KHOSRAVl V, GHOLIZADEH A,AGYEMAN P C,et al. Further to quantification of content, can reflectance spectroscopy determine the speciation of cobalt and nickel on a mine waste dump surface [j]. Science of the Total Environment, 2023 ,872; 161996.

TAN K,MA W, CHEN L,et al. Estimating the distribution trend of soil heavy metals in mining area from HyMap airborne hyperspectral imagery based on ensemble learning [j]. Hazard Mater,2021 ,401 ; 123288.

ZOU B, JIANG X L, FENG H H,et al. Multisource spectral-integrated estimation of cadmium concentrations in soil using a direct standardization and Spiking algorithm [J ]. Science of the Total Environment, 2020, 701 :134890.

WANG X, AN S, XU Y Q. A back propagation neural network model optimized by mind evolutionary algorithm for estimating Cd, Cr, and Pb concentrations in soils using Vis-NIR diffuse reflectance spectroscopy[ J ]. Applied Sciences, 2020, 10( 1 ) : 51.

CHENG Yongsheng, ZHOU Yao. Research progress and trend of quantitative monitoring of hyperspectral remote sensing for heavy metals in soil; [J ]. The Chinese Journal of Nonferrous Metals, 2021 , 31(11) :3450 -3467. (in Chinese)

SUN Weichao. Estimation of heavy metal concentration in soil using hyperspectral remote sensing based on the sorptionon spectrally active soil constituents [D]. Beijing: University of Chinese Acdemy of Sciences,2019. (in Chinese)

SUN W C,LIU S,ZHANG X,et al. Performance of hyperspectral data in predicting and mapping zinc concentration in soil [J] . Science of the Total Environment,2022 ,824 ; 153766.

SUN W C,ZHANG X,SUN X J,et al. Predicting nickel concentration in soil using reflectance spectroscopy associated with organic matter and clay minerals[ J]. Geoderma, 2018, 327 ;25 -35.

YANG H F,XU H, ZHONG X N. Prediction of soil heavy metal concentrations in copper tailings area using hyperspectral reflectance[ J] . Environmental Earth Sciences,2022 ,81 (6) : 183.

TAN K,WANG H M ,CHEN L H,et al. Estimation of the spatial distribution of heavy metal in agricultural soils using airborne hyperspectral imaging and random forest J . Journal of Hazardous Materials,2020, 382:120987.

YANG Yang, HUANG Weihao,LU Ying,et al. Spectral characteristics and quantitative retrieval of free iron content in soil [J] . Journal of South China Agricultural University,2020,41 ( 1 ) ;91 -99. (in Chinese)

ZHAO L, HU Y M, ZHOU W,et al. Estimation methods for soil mercury content using hyperspectral remote sensing [J ] . Sustainability,2018, 10(7) :2474.

ZHOU Bing, LI Bingxuan,HE Xuan,et al. Classification of camouflages using hyperspectral images combined with fusing adaptive sparse representation and correlation coefficient [ J ]. Spectroscopy and Spectral Analysis, 2021 .41 ( 12) : 385 1 - 3856. (in Chinese)

JIANG Xiaoyu,LI Fusheng,WANG Qingya,et al. Determination of lead and arsenic in soil samples by X fluorescence spectrum combined with CARS variables screening method [ J ]. Spectroscopy and Spectral Analysis, 2022,42(5 ) ; 1535 - 1540. ( in Chinese)

PAVEZ L В,SOTO C. A deterministic annular crossover genetic algorithm optimisation for the unit commitment problem [J]. Expert Systems with Applications, 2021 ,38(6) ;6523 -6529.

VOHLAND M,HARBICH M,LUDWIG M,et al. Quantification of soil variables in a heterogeneous soil region with VIS — MR - SWIR data using different statistical sampling and modeling strategies[ J]. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 2016,9(9) :4011 -4021.

VOHLAND M, LUDWIG M, THIELE-BRUHN S,et al. Quantification of soil properties with hyperspectral data: selecting spectral variables with different methods to improve accuracies and analyze prediction mechanisms [J ]. Remote Sensing, 2017,