三种环境材料混施对高寒矿区边坡土壤的影响
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作者单位:

1.College of Water Sciences,Beijing Normal University;2.School of Chemical and Environmental Engineering;3.中国矿业大学(北京)

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中图分类号:

S156

基金项目:

青海威斯特铜业有限责任公司科研项目 “高寒矿区边坡绿化喷播基质配制及其应用技术研究”(2641-ZC-2022-00094)


Effect of mixed application of three environmental materials on slope soils in alpine mining areas
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Qinghai West Copper Limited Liability Company Scientific Research project"Research on the preparation and application technology of slope greening and spraying substrate in alpine mining area"(2641-ZC-2022-00094)

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    摘要:

    [目的] 为解决青藏高寒地区土壤复垦过程中土壤结构较差、水土侵蚀严重等问题,[方法] 以青海德尔尼铜矿为例,利用当地蛇纹石渣土和原土,通过土培模拟正交试验,研究了混施粘合剂、长纤维、稻壳 3 种材料对边坡土壤改良的效果,并筛选出效果最佳的混合材料比例。[结果] 正交极差结果表明:粘合剂对土壤团聚体、总孔隙度、田间持水量和土壤容重的影响较强,长纤维和稻壳对pH和全盐含量的影响较强。与对照相比(CK)相比,粘合剂的加入可以增加土壤容重,但会降低土壤孔隙;长纤维和稻壳可明显降低土壤pH,提高总孔隙度和田间持水量并适当提高全盐含量。土壤团聚体和pH最优的组合为 A2B2C3(粘合剂0.074 g·kg-1,长纤维2.96 g·kg-1,稻壳11.11 g·kg-1);土壤容重、总孔隙度和田间持水量调节以 A1B2C2(粘合剂0.037 g·kg-1,长纤维2.96 g·kg-1,稻壳7.41 g·kg-1)组合最优;全盐含量最优组合为 A3B1C2(粘合剂0.111 g·kg-1,长纤维1.48 g·kg-1,稻壳7.41 g·kg-1)。[结论] 综合考虑,通过中值法得到高寒矿区土壤基质恢复最优配方结果是A1.5B2C2,即A(粘合剂)0.0555 g·kg-1,B(长纤维)2.96 g·kg-1,C(稻壳)7.41 g·kg-1为最优配比。有利于青藏高寒矿区土壤结构的恢复和稳定,对青藏高寒矿区水土保持有重要的作用。

    Abstract:

    [Objective] In order to solve the problems of poor soil structure and serious soil erosion in the process of soil reclamation in the alpine region of Qinghai-Tibet, [Methods] the Delni copper mine in Qinghai was taken as an example. Using the local serpentine residue soil and the original soil, the effect of mixing and applying three kinds of materials—binder, long fiber, and rice husk—on the improvement of the soil of the side slopes was investigated through an orthogonal test of soil cultivation simulation. The proportion of the mixing materials with the best effect was determined. [Results] Orthogonal polar results showed that the binder had a stronger effect on soil aggregates, total porosity, field water holding capacity, and soil bulk density, while long fibers and rice husk had a stronger effect on pH and total salt content. Binder incorporation increased soil bulk density but decreased soil pore space compared to the control (CK). Long fibers and rice husk significantly decreased soil pH, increased total porosity and field water holding capacity, and appropriately increased total salt content. The optimal combination for soil aggregates and pH was A2B2C3 (binder 0.074 g·kg-1, long fiber 2.96 g·kg-1, rice husk 11.11 g·kg-1). Soil bulk density, total porosity, and field water holding capacity regulation were optimized with the combination A1B2C2 (binder 0.037 g·kg-1, long fiber 2.96 g·kg-1, rice husk 7.41 g·kg-1), and the optimal combination for total salt content was A3B1C2 (binder 0.111 g·kg-1, long fiber 1.48 g·kg-1, rice husk 7.41 g·kg-1). [Conclusion]Taken together, the optimal formulation for soil matrix restoration in alpine mining areas was obtained by the median method as A1.5B2C2, i.e., A (binder) 0.0555 g·kg-1, B (long fibers) 2.96 g·kg-1, and C (rice husk) 7.41 g·kg-1. This formulation is conducive to the restoration and stabilization of soil structure in the Qinghai-Tibet alpine mining area and plays an important role in soil and water conservation in this region.

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  • 收稿日期:2024-05-31
  • 最后修改日期:2024-09-12
  • 录用日期:2024-09-12
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