Your search keyword '"Jurate Kumpiene"' showing total 4 results

1. Leaching of metal(loid)s from ashes of spent sorbent and stabilisation effect of calcium-rich additives

Author

Marcus Öhman, Alfreda Kasiuliene, Hamid Sefidari, Prosun Bhattacharya, Jurate Kumpiene, and Ivan Carabante

Subjects

Sorbent, Health, Toxicology and Mutagenesis, Lime, Thermochemical equilibrium calculations, chemistry.chemical_element, Incineration, 02 engineering and technology, 010501 environmental sciences, engineering.material, Coal Ash, 01 natural sciences, Arsenic, Hazardous waste, Metals, Heavy, Environmental Chemistry, Leachate, 0105 earth and related environmental sciences, Minerals, Waste management, General Medicine, Iron-coated peat, Contamination, 021001 nanoscience & nanotechnology, Pollution, Refuse Disposal, Waste Disposal Facilities, Heavy metals, chemistry, engineering, Environmental science, Calcium, Leaching (metallurgy), 0210 nano-technology, Research Article

Abstract

Contaminated water with multiple contaminants, including As, Cr, Cu and Zn, was treated with a sorbent prepared by coating peat with Fe oxides. Because As has a relatively little explored market, the regeneration of the spent sorbent was not feasible. Meanwhile, the disposal of As wastes in landfills can cause landfill leachate treatment problems. Under the reducing conditions prevailing at landfills, As(V) is reduced to As(III), which is a toxic and more mobile form. In this study, incineration was explored as a management option to treat the spent sorbent that was loaded with As, Cr, Cu and Zn. The first objective of this study was to evaluate the leaching of these metal(loid)s from the ashes and compare it with the leaching from the spent sorbents before incineration. The second objective was to evaluate the leaching behaviour when the spent sorbent was co-incinerated with a Ca-rich additive (lime). To achieve these objectives, the obtained ashes were subjected to leaching tests, sequential extraction, and X-ray diffraction analyses. After the incineration, the ash content ranged from 9 to 19% of the initial mass of the spent sorbents. The leaching of As, Cu and Zn decreased compared with that from the spent sorbents before the thermal treatment because of the high incineration temperatures and/or co-incineration with lime. However, the leaching of Cr increased, which would hinder the disposal of the obtained ashes in a landfill because the limit value for disposal at a landfill for hazardous wastes was exceeded by 50 times. However, co-incineration with 10 wt% lime significantly decreased the leaching of Cr as a result of the formation of water-insoluble Ca-Cr compounds. Electronic supplementary material The online version of this article (10.1007/s11356-020-09269-z) contains supplementary material, which is available to authorized users.

Published

2020

2. Hydrothermal carbonisation of peat-based spent sorbents loaded with metal(loid)s

Author

Prosun Bhattacharya, Jurate Kumpiene, Ivan Carabante, and Alfreda Kasiuliene

Subjects

Health, Toxicology and Mutagenesis, chemistry.chemical_element, Zinc, 010501 environmental sciences, 01 natural sciences, Hydrothermal circulation, Soil, Chromium, Adsorption, Environmental Chemistry, Thermal treatment, Organic matter, Biomass, Post-sorption management, Arsenic, Metalloids, 0105 earth and related environmental sciences, chemistry.chemical_classification, Temperature, HTC, General Medicine, Pollution, Carbon, Manure, Iron-peat, chemistry, Metals, Leaching (metallurgy), Research Article, Nuclear chemistry

Abstract

Hydrothermal carbonisation (HTC) is a wet and relatively low-temperature process where, under autogenous pressures, biomass undergoes a chain of reactions leading to the defragmentation of organic matter. As well as its other uses (e.g. for producing low-cost carbon-based nano-compounds), HTC is utilised for the treatment of wet wastes, such as manure and biosludge. This study aimed to determine if hydrothermal carbonisation is a feasible treatment method for spent sorbents that are highly enriched with arsenic, chromium, copper, and zinc. The chemical properties of hydrochar and process liquid were evaluated after HTC treatment, where peat-based spent sorbents were carbonised at 230 °C for 3 h. Analysis of Fourier transform-infrared spectra revealed that during HTC, the oxygenated bonds of ethers, esters, and carboxylic groups were cleaved, and low-molecular-weight organic fragments were dissolved in the process liquid. A large fraction of arsenic (up to 62%), copper (up to 25%), and zinc (up to 36%) were transferred from the solids into the process water. Leaching of these elements from the hydrochars increased significantly in comparison with the spent sorbents.

Published

2019

3. Utilization of air pollution control residues for the stabilization/solidification of trace element contaminated soil

Author

Anders Kihl, Jurate Kumpiene, and Igor Travar

Subjects

chemistry.chemical_classification, Soil test, Chemistry, Health, Toxicology and Mutagenesis, Soil organic matter, Environmental engineering, Soil classification, Incineration, General Medicine, Calcium Compounds, Coal Ash, Pollution, Soil contamination, Soil conditioner, Soil, Metals, Heavy, Environmental chemistry, Arsenates, Soil Pollutants, Environmental Chemistry, Organic matter, Leaching (agriculture), Environmental Pollution, Waste disposal

Abstract

The aim of this study was to evaluate the stabilization/solidification (S/S) of trace element-contaminated soil using air pollution control residues (APCRs) prior to disposal in landfill sites. Two soil samples (with low and moderate concentrations of organic matter) were stabilized using three APCRs that originated from the incineration of municipal solid waste, bio-fuels and a mixture of coal and crushed olive kernels. Two APCR/soil mixtures were tested: 30 % APCR/70 % soil and 50 % APCR/50 % soil. A batch leaching test was used to study immobilization of As and co-occurring metals Cr, Cu, Pb and Zn. Solidification was evaluated by measuring the unconfined compression strength (UCS). Leaching of As was reduced by 39–93 % in APCR/soil mixtures and decreased with increased amounts of added APCR. Immobilization of As positively correlated with the amount of Ca in the APCR and negatively with the amount of soil organic matter. According to geochemical modelling, the precipitation of calcium arsenate (Ca3(AsO4)2/4H2O) and incorporation of As in ettringite (Ca6Al2(SO4)3(OH)12 · 26H2O) in soil/APCR mixtures might explain the reduced leaching of As. A negative effect of the treatment was an increased leaching of Cu, Cr and dissolved organic carbon. Solidification of APCR/soil was considerably weakened by soil organic matter.

Published

2015

4. Utilisation of chemically stabilized arsenic-contaminated soil in a landfill cover

Author

Evelina Brännvall, Jurate Kumpiene, Sven Schulenburg, Mariarita Arenella, Lale Andreas, Anders Lagerkvist, Paolo Desogus, Giancarlo Renella, and Rolf Sjöblom

Subjects

Soil test, Health, Toxicology and Mutagenesis, Industrial Waste, Coal Ash, complex mixtures, Arsenic, Soil, Amendments, Enzyme activity, Immobilisation, Toxicity, Zerovalent iron, Environmental Monitoring, Environmental Restoration and Remediation, Refuse Disposal, Sewage, Soil Pollutants, Waste Disposal Facilities, Environmental Chemistry, Soil organic matter, Environmental engineering, Soil chemistry, Soil classification, General Medicine, Pollution, Soil contamination, Leaching model, Soil conditioner, Environmental science, Soil horizon, Research Article

Abstract

The aim of the study was to determine if an As-contaminated soil, stabilized using zerovalent iron (Fe(0)) and its combination with gypsum waste, coal fly ash, peat, or sewage sludge, could be used as a construction material at the top layer of the landfill cover. A reproduction of 2 m thick protection/vegetation layer of a landfill cover using a column setup was used to determine the ability of the amendments to reduce As solubility and stimulate soil functionality along the soil profile. Soil amendment with Fe(0) was highly efficient in reducing As in soil porewater reaching 99 % reduction, but only at the soil surface. In the deeper soil layers (below 0.5 m), the Fe treatment had a reverse effect, As solubility increased dramatically exceeding that of the untreated soil or any other treatment by one to two orders of magnitude. A slight bioluminescence inhibition of Vibrio fischeri was detected in the Fe(0) treatment. Soil amendment with iron and peat showed no toxicity to bacteria and was the most efficient in reducing dissolved As in soil porewater throughout the 2 m soil profile followed by iron and gypsum treatment, most likely resulting from a low soil density and a good air diffusion to the soil. The least suitable combination of soil amendments for As immobilization was a mixture of iron with coal fly ash. An increase in all measured enzyme activities was observed in all treatments, particularly those receiving organic matter. For As to be stable in soil, a combination of amendments that can keep the soil porous and ensure the air diffusion through the entire soil layer of the landfill cover is required.

Published

2013