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Experimental Study on Quantitative Inversion Model of Heavy Metals in Soda Saline-Alkali Soil Based on RBF Neural Network |
FU Yan-hua1, LIU Jing2*, MAO Ya-chun2, CAO Wang2, HUANG Jia-qi2, ZHAO Zhan-guo3 |
1. School of Resources and Civil Engineering, Northeastern University, Shenyang 110819, China
2. School of Architecture, Northeastern University, Shenyang 110819, China
3. China Gold Group, Beijing 100000, China
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Abstract Soil is an important part of the natural ecosystem and an important material basis for human survival and agricultural production. With the rapid socio-economic development, the high-intensity industrial and agricultural production activities lead to various pollutants such as heavy metals entering the soil through atmospheric deposition and sewage irrigation and continuously enriching in the soil, causing soil salinization and soil heavy metal pollution, both of which are the main causes of global desertification and soil degradation. However, China has very limited arable land, and food security is especially important. Therefore, quickly and accurately invert the heavy metal content of saline land in a large area is an important research topic to ensure food security. This paper establishes a quantitative inversion model of the heavy metal content of manganese (Mn), cobalt (Co) and iron (Fe) in saline land with soil visible-near infrared spectral data in Zhenlai County, Jilin Province. Firstly, Savitzky-Golay smoothing, multiple scattering correction and continuous statistical de-transformation were performed on the raw spectral data respectively; then three spectral indices, namely, ratio (RI), the difference (DI) and normalized (NDI), were constructed based on the pre-processed spectral data, and the model training samples were determined by correlation analysis between the spectral indices and heavy metal contents. The radial basis neural network algorithm was used to model and invert the saline heavy metal contents. Finally, the sensitive band combinations with significant correlation between the spectral indices and the contents of Mn, Co and Fe were determined by the accuracy analysis method of the gradient cycle modeling such as correlation coefficient and the optimal inversion model based on the radial basis neural network algorithm was established for the heavy metal content of saline land. The results show that the correlation coefficients r>0.70 for Mn, r>0.80 for Co, and r>0.80 for Fe. The selected combinations of sensitivity indices are 108, 690, and 31 groups, respectively, and the optimal inversion models R2 for Mn, Co, and Fe based on the above significant combinations of sensitivity indices are 0.703 4, 0.897 6. The RMSEs were 53.007 3, 1.059 2 and 0.363 4, and the average relative accuracies were 88.64%, 90.36% and 91.78%, respectively. This study provides an effective method for accurate and rapid analysis of heavy metal content in saline soils, which is of great practical importance for achieving soil heavy metal pollution control.
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Received: 2021-03-23
Accepted: 2021-06-09
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Corresponding Authors:
LIU Jing
E-mail: 1800988@stu.neu.edu.cn
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[1] XU Xiao-hong,LIU Su,ZHAO Ying-jie,et al(许晓鸿,刘 肃,赵英杰,等). Bulletin of Soil and Water Conservation(水土保持通报),2018,38(1):89.
[2] ZHAO Dong-jie,WANG Xue-qiu(赵东杰,王学求). China Environmental Science(中国环境科学),2020,40(4):1609.
[3] CHEN Yu-bo,XUE Yun,ZOU Bin,et al(陈宇波,薛 云,邹 滨,等). Journal of Central South University(中南大学学报),2020,51(10):2876.
[4] ZHANG Qiu-xia,ZHANG He-bing,LIU Wen-kai,et al(张秋霞,张合兵,刘文锴,等). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报),2017,33(12):230.
[5] TU Yu-long,ZOU Bin,JIANG Xiao-lu,et al(涂宇龙,邹 滨,姜晓璐,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2018,38(2):575.
[6] XU Li-hua,XIE De-ti(徐丽华,谢德体). Jiangsu Journal of Agricultural Sciences(江苏农业学报),2019,35(6):1340.
[7] CHENG Xian-feng,SONG Ting-ting,CHEN Yu,et al(程先锋,宋婷婷,陈 玉,等). Acta Petrologica et Mineralogica(岩石矿物学杂志),2017,36(1):60.
[8] Tan Kun,Ma Weibo,Chen Lihua,et al. Journal of Hazardous Materials,2021,401:123288.
[9] Mao Yachun,Liu Jing,Cao Wang,et al. Infrared Physics and Technology,2021,112:103602.
[10] LEI Lin-ping(雷林平). Computer and Information Technology(电脑与信息技术),2014,22(5):30.
[11] WANG Tao,BAI Tie-cheng,ZHU Cai-die,et al(王 涛,白铁成,朱彩蝶,等). Journal of Northwest Forestry University(西北林学院学报),2020,35(5):173.
[12] WEN Ping,LI Hai-jun,LEI He-yu,et al(闻 萍,李海军,雷禾雨,等). Journal of Inner Mongolia Agricultural University(内蒙古农业大学学报),2021,42(2):79.
[13] SONG Chun-yu,GAN Shu,YUAN Xi-ping,et al(宋春雨,甘 淑,袁希平,等). Acta Agriculturae Zhejiangensis(浙江农业学报),2020,32(11):1978.
[14] WU Zhong-qiang,MAO Zhi-hua,WANG Zheng,et al(吴忠强,毛志华,王 正,等). Hydrographic Surveying and Charting(海洋测绘),2019,39(3):11.
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