Simultaneous quantification of multiple chemical properties of soil solution using smart spectroscopy

Purpose Soil environmental monitoring is crucial for crop production, urban planning, and human health. However, the existing monitoring methods are inefficient and costly. In order to improve the efficiency of soil monitoring, a multi-indicator concentration detection method based on a new modified...

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Bibliographic Details
Published in:Journal of soils and sediments 2024-04, Vol.24 (4), p.1694-1703
Main Authors: Zhao, Yuting, Feng, Yunjin, Liu, Lu, Wan, Qianru, Guo, Zhiqiang, Lei, Jingzheng, Wang, Wenjing, Liu, Fenli, Duan, Qiannan, Lee, Jianchao
Format: Article
Language:English
Subjects:
Artificial neural networks
Chemical properties
Chemicophysical properties
Crop production
Earth and Environmental Science
Environment
Environmental monitoring
Environmental Physics
human health
Machine learning
Monitoring
Monitoring methods
Neural networks
prediction
Prediction models
Root-mean-square errors
Sec 3 • Remediation and Management of Contaminated or Degraded Lands • Research Article
Soil
Soil chemistry
Soil properties
Soil Science & Conservation
Soil solution
Soils
spectrometers
Spectroscopy
Spectrum analysis
Urban planning
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Summary:Purpose Soil environmental monitoring is crucial for crop production, urban planning, and human health. However, the existing monitoring methods are inefficient and costly. In order to improve the efficiency of soil monitoring, a multi-indicator concentration detection method based on a new modified spectrometer technology (MST) was proposed. Materials and methods MST, a method that combines high-throughput experiments (HTE) and machine learning (ML), was proposed to determine various substances in a complex environment and exhibited features of large measurement throughput and high prediction accuracy. Soil is a classic complex chemical system in nature, so we want to try to apply MST to soil monitoring projects. In this study, about 14,400 holographic scattering spectroscopy (HSS) images were captured using the MST and used to train 3 deep neural networks (ResNet-50, Inception V1, and SqueezeNet V1.1). These models were optimized by adjusting parameters and hyperparameters. Results and discussion The concentration prediction model based on ResNet-50 has fast convergence speed and a good learning effect. The model can simultaneously detect eight indicators. The best evaluation results achieved coefficient of determination ( R 2 ) = 0.996, root mean square error (RMSE) = 0.758, and mean relative error (MRE) 
ISSN:1439-0108
1614-7480
DOI:10.1007/s11368-024-03747-4