Assessing the impact of preload on pyrite-rich sediment and groundwater quality

Karikari-Yeboah, Ohene; Addai‐Mensah, Jonas

doi:10.1007/s10661-017-5771-3

Cited by 6 publications

(1 citation statement)

References 38 publications

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“…Previous studies have found that the changes in water chemistry following earthquakes are related to the minerals being exposed to fluids [ 6 , 7 ]. Changes in water chemistry may also be due to the change in redox conditions [ 8 ]. In addition, when water flows through the reactive fine-grained material [ 9 ], it could act as a solute generator affecting water quality [ 10 , 11 ].…”

Section: Introductionmentioning

confidence: 99%

Soil Column Experimental Study on the Effect of Soil Structure Disturbance on Water Chemistry

Long

Huang

Zhang

et al. 2022

IJERPH

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The changes in soil/rock structure caused by engineering disturbance or earthquakes could affect water chemistry by increasing the reaction surface, enhancing the oxidation condition, or exposing soluble rocks. However, the details of the mechanisms of the disturbance of soil/rock are little known. Based on the soil column experiment, this study analyzed the concentrations of sulfate (SO4), sulfur, and oxygen isotopic composition of SO4 (δ34S-SO4 and δ18O-SO4) in effluent water. The water–rock interaction mechanisms in the disturbed soil and the contribution of this interaction to the SO4 in groundwater were studied. The results suggest that the concentration of SO4 in the first effluent water sample can reach up to 97 mg/L, much higher than that in natural groundwater (6.8 mg/L). The isotopic composition of SO4 further suggested that SO4 in the first effluent water sample was mainly derived from the dissolution of SO4-containing evaporites. The proportion was estimated to be 93%. SO4-containing evaporites accounted for 23% of the SO4 content in all effluent water samples during the experiment. The disturbance of soil structure led to the exposure and dissolution of SO4-containing evaporites, which were initially insoluble under natural conditions. This study is essential to the clarification of the water–rock interaction mechanisms following the changes in soil/rock structures.

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Section: Introductionmentioning

confidence: 99%

Soil Column Experimental Study on the Effect of Soil Structure Disturbance on Water Chemistry

Long

Huang

Zhang

et al. 2022

IJERPH

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Assessing Solute Transport and Pollutant Fate: Insights from Coastal Soil and Water Interactions

Ramaraju,

Kiran

2024

Lecture Notes in Civil Engineering

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The impact of preload on the mobilisation of multivalent trace metals in pyrite-rich sediment

Karikari-Yeboah

Skinner

Addai‐Mensah

2018

Environ Monit Assess

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Trace metals occur at various concentrations in all wetlands. Their proliferation, chemical speciation, mobility and bioavailability are dependent on the redox potential (Eh), pH and the presence of organic and inorganic adsorption surfaces and co-precipitating metals. Consequently, changes in these key parameters have the potential to alter the fate of the dominant trace metal species in the sediment. An imposition of preload surcharge is a technique use in geotechnical engineering to improve in the strength and load carrying capacity of waterlogged sediments. The soil strength improvement is effected through the expulsion of porewater from the sediment. The imposition of surcharge over wetland sediments has the potential to create oxygen-deficient condition within the sediment, and cause pH, temperature, redox, EC and salinity changes in the sediment, which would impact on the mobilisation, chemical speciation, mobility and bioavailability of dominant toxic trace metals and their toxicity in the sediment. In the present work, a case study of the impact of preload surcharge on the proliferation, chemical speciation, mobilisation, mobility and bioavailability of arsenic, chromium, cobalt, copper and zinc in a naturally occurring pyrite-rich sediment is presented. The imposition of preload surcharge over the pyrite-rich sediment was accompanied by changes in the redox dynamics of the sediment, with multi-facet impact on the concentration, mobilisation and bioavailability of toxic trace metals, their redox transformation between oxidation states and on the toxicity within and outside the sediment environment.

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Assessing the impact of preload on pyrite-rich sediment and groundwater quality

Cited by 6 publications

References 38 publications

Soil Column Experimental Study on the Effect of Soil Structure Disturbance on Water Chemistry

Soil Column Experimental Study on the Effect of Soil Structure Disturbance on Water Chemistry

Assessing Solute Transport and Pollutant Fate: Insights from Coastal Soil and Water Interactions

The impact of preload on the mobilisation of multivalent trace metals in pyrite-rich sediment

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