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Detection of soil physical properties of reclaimed land in open-pit mining area: feasibility of application of ground penetrating radar

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Abstract

In order to obtain the typical soil physical properties of reclaimed land more quickly and accurately, the South Dump of the China Coal’s Antaibao Open-Pit Mine in Pingshuo was focussed on in this paper, and ground penetrating radar (GPR) technology was utilized to detect the soil physical properties of reclaimed land in the mining area. The soil profile sampling and GPR detection methods were used to acquire the data. The gravel content of surface soil was analyzed by counting the number of isolated gravel signals in GPR images. The change of effective soil thickness was analyzed by establishing the fitting relationship between calibration depth and GPR image depth. The Topp’s model was validated by comparing its inversion with the measured soil volumetric water content. And the Topp’s model was further validated by the soil volumetric water content obtained from the Topp’s model and which obtained from the wave velocity inversion. The results are as follows: (1) Based on the number of isolated gravel signals in GPR images, we could qualitatively analyze the gravel content of surface soil reclaimed in the mining area. As the number of isolated gravel signals was greater, the gravel content of the surface soil was higher. (2) Using the known relative permittivity, electromagnetic wave velocity, and soil volumetric water content, the calibration depth and the reflection depth of the target (calibrator) of the GPR images were segmented, and the correlation between them is high. The fitting relationship (R2) of each segment was higher than 0.940, and the average value of the five-segment R2 was 0.966, which indicated more accurate detection of the effective soil thickness of the reclaimed land in the mining area. (3) GPR could be used to detect the soil volumetric water content of reclaimed land in mining area, and Topp’s model was used for calculation of soil volumetric water content. The average deviation rate between the values from Topp’s model and the measured values was 12%, and the average absolute value of the difference was 2%. In summary, the benefits of using GPR to detect soil physical properties of reclaimed land in mining area are as follows: (1) GPR can be used to detect soil layer thickness and surface gravel content faster and more accurately. (2) Topp model can also be used to calculate the soil moisture content of non-natural deposits such as reclaimed land in mining area.

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Funding

This work was supported by the National Natural Science Foundation of China (U1810107, 41701607) and the Project for Basic Scientific Research of the Central Universities (2–9-2018–025 and 2–9-2019–307).

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Authors and Affiliations

  1. School of Land Science and Technology, China University of Geosciences, Beijing, 100083, China

    Gubai Luo, Yingui Cao, Hanxiao Xu, Geng Yang, Shufei Wang, Yuhan Huang & Zhongke Bai

  2. Key Laboratory of Land Consolidation and Rehabilitation, Ministry of Natural Resources, Beijing, 100035, China

    Yingui Cao & Zhongke Bai

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  1. Gubai Luo
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  2. Yingui Cao
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  3. Hanxiao Xu
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  4. Geng Yang
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  7. Zhongke Bai
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Correspondence to Yingui Cao.

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Luo, G., Cao, Y., Xu, H. et al. Detection of soil physical properties of reclaimed land in open-pit mining area: feasibility of application of ground penetrating radar. Environ Monit Assess 193, 392 (2021). https://doi.org/10.1007/s10661-021-09153-4

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