Assessing the Use of Magnetic Methods to Monitor Vertical Migration of Metal Pollutants in Soil

Sapkota, B.; Cioppa, M. T.

doi:10.1007/s11270-011-0911-9

Cited by 12 publications

(2 citation statements)

References 31 publications

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“…In spite of the fact that the depth of the upper (anthropogenic) maxima in the soil profile is rather related to profile development, soil type, thickness of organic horizon etc. however certain migration of magnetic particles over the years between O and Ah horizons is not excluded (Sapkota and Cioppa, 2012;Dlouha et al, 2013).…”

Section: Vertical Changesmentioning

confidence: 99%

Spatial variation of soil magnetic susceptibility in relation to different emission sources in southern Poland

et al. 2015

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Section: Vertical Changesmentioning

confidence: 99%

Spatial variation of soil magnetic susceptibility in relation to different emission sources in southern Poland

et al. 2015

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“…The change in groundwater pressure affects the low-pressure area under the overburden and has different effects on various layers [28]. Due to the complexity of mechanical properties under different stratum conditions, the impact of subsidence on the movement of pollutants in different strata is different [29]. HS-GCMS analysis indicated that benzene content decreased significantly with the increase in soil depth [30].…”

Section: Introductionmentioning

confidence: 99%

Effect of Pumping Speeds on the Fate of Aniline in Different Soil Layer

Gao,

Wang,

et al. 2024

Sustainability

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Helan Mountain is an important ecological safety barrier in northwest China. In this study, a heterogeneous site polluted by aniline on Helan Mountain was the research object, and the TMVOC (A Simulator For Multiple Volatile Organic Chemicals) model of aniline restoration by pumping was optimized by employing a column experiment. Four typical layers of the soil medium were selected to explore the influence of soil settlement caused by different pumping speeds on the fate of aniline in different zones. The results show that the optimal pumping speed at the site is 3.24 × 106 m3/month and the latest remediation time is the 10th month after the start of the remediation. The larger the pumping speed is, the more obvious the sedimentation effect is. When the remediation is carried out at 5.18 × 106 m3/month, the NAPL (Non-Aqueous-Phase Liquid) phase removal rate decreases by 33.75% and the distribution of aniline to the NAPL phase increases, compared to that without considering the soil settlement. The fate of aniline in the source zone is the least affected by sedimentation, while that in the vadose zone is the most affected. The phase redistribution phenomenon is the most obvious in the water table fluctuation zone, and the NAPL phase aniline changes into gas and liquid phases. In addition, the NAPL phase concentration in the water table fluctuation zone is two orders of magnitude higher than that at 0.2 m below the water table. NAPL is the most sensitive to the relative settlement in the aquifer. The simulation results can provide a technical reference for the future application of P&T (Pump-and-Treat) technology in the remediation of organically contaminated sites to facilitate the sustainable use of soil. It is suggested that more attention should be paid to the water table fluctuation zone during the remediation of contaminated sites.

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