Your search keyword '"Phosphogypsum contamination"' showing total 10 results

1. Assessment and Mitigation of Groundwater Contamination from Phosphate Mining in Tunisia: Geochemical and Radiological Analysis.

Author

Hamed, Younes, Gentilucci, Matteo, Mokadem, Naziha, Khalil, Rayan, Ayadi, Yosra, Hadji, Riheb, and Elaloui, Elimame

Subjects

PHOSPHATE mining, ANALYTICAL geochemistry, GROUNDWATER, GEOTHERMAL resources, RADIOACTIVE elements, PHOSPHATE rock, AQUIFERS, GYPSUM

Abstract

Groundwater contamination in the Mediterranean Basin is a severe problem that has a significant impact on environmental ecosystems and human health. The unconventional uranium and the potentially toxic elements (PTEs) of phosphate rocks are the principal contaminants in the phosphate mining industry in Tunisia. Phosphogypsum (PG) results from the valorization of phosphate to fertilizers and phosphoric acid. PG stocks can be used in cement production, brick manufacturing, and soil amendments in desertic land, and can be resolved by using nanomaterial adsorbents. In the flat area of the study area, the increase in radioactivity (40K) is due to abusive fertilizer use. Geochemical and radiological analyses in the northern part of Tunisia and its karst shallow aquifer indicate significant contamination levels. The northern part exhibits moderate contamination, whereas the karst shallow aquifer shows higher contamination levels, particularly with elevated nitrate concentrations. In the phosphate basin, both washing phosphate and phosphogypsum reveal high levels of radioactive elements, with the latter showing especially high concentrations of radium. The shallow aquifer in this region has moderate contamination levels, while the deep geothermal aquifer also shows noticeable contamination but to a lesser degree compared to the shallow aquifer. The shallow groundwater is characterized by a higher value of radioactivity than the groundwater due to the contamination impact from the phosphate industry and the cumulative radioactivity disintegration. Finally, the nanoparticles and the electrostatic adsorption can decrease the PTEs and radionuclides from the contaminated water in the study area. Moreover, other key issues for advancing research on groundwater contamination are proposed in this study. It is time to valorize this PG and the other mines of (Fe, Pb, and Zn) in the socioeconomic sector in Tunisia and to minimize the environmental impact of the industrial sector's extraction on groundwater and human health in the study area. [ABSTRACT FROM AUTHOR]

Published

2024

2. Marine sediments in the Gulf of Gabes (Tunisia) heavily polluted by phosphogypsum and human microbiota bacteria: phytoremediation by Salicornia europaea as a natural-based solution.

Author

Rajhi, Hayfa, Sanz, Jose Luis, Bardi, Anouar, and Rojas, Patricia

Subjects

PHOSPHOGYPSUM, HUMAN microbiota, PHYTOREMEDIATION, CONTAMINATED sediments, MARINE bacteria, BACTERIA

Abstract

A huge amount of phosphogypsum (PG) wastes generated from the processing phosphate ore in Tunisia Industrial Group Area—Gabes is getting discarded into the sea. Within this framework, the basic objective of this research is to elaborate and discuss a natural-based solution focused on phytoremediation of contaminated (PG) soils and marine sediments with the halophilic plant Salicornia europaea. A significant drop of the organic matter (53.09%), moisture (26.47%), and sediment porosity with (5.88%) was detected in the rhizosphere Salicornia europaea area (RS). Removal of hazardous elements concentrations, such as Pb, Fe, Cu, Cd, and Zn, between contaminated sediment (CS) and RS displayed a significant difference, ranging from 5.33 to 50.02% of hazardous elements removal concentration, which was observed in the rhizosphere zone. The microbiota of both areas (RS and CS) were analyzed by massive sequencing. In both samples, all the sequences belong to only four phyla: Firmicutes and, to a much lower extent, Proteobacteria, Bacteroidetes, and Actinobacteria. The CS sediment seems to be heavily polluted by human activities. Most of the found genera are inhabitants of the intestine of warm-blooded animals (Escherichia, Bacteroides, Prevotella, Faecalibacterium, Ruminococcus, Enterococcus); hence, activities in this area pose a health risk. On the other hand, it may be surprising that 76.4% of the total high-quality sequences retrieved from the RS sample were affiliated to the family Bacillaceae. The salinity of the studied soil exerts a stress on the microbial populations that inhabit it, directing the selection of halotolerant species. [ABSTRACT FROM AUTHOR]

Published

2024

3. Assessment and Mitigation of Groundwater Contamination from Phosphate Mining in Tunisia: Geochemical and Radiological Analysis

Author

Younes Hamed, Matteo Gentilucci, Naziha Mokadem, Rayan Khalil, Yosra Ayadi, Riheb Hadji, and Elimame Elaloui

Subjects

groundwater contamination, phosphate mining, uranium, potential toxic elements, phosphogypsum contamination, Science

Abstract

Groundwater contamination in the Mediterranean Basin is a severe problem that has a significant impact on environmental ecosystems and human health. The unconventional uranium and the potentially toxic elements (PTEs) of phosphate rocks are the principal contaminants in the phosphate mining industry in Tunisia. Phosphogypsum (PG) results from the valorization of phosphate to fertilizers and phosphoric acid. PG stocks can be used in cement production, brick manufacturing, and soil amendments in desertic land, and can be resolved by using nanomaterial adsorbents. In the flat area of the study area, the increase in radioactivity (40K) is due to abusive fertilizer use. Geochemical and radiological analyses in the northern part of Tunisia and its karst shallow aquifer indicate significant contamination levels. The northern part exhibits moderate contamination, whereas the karst shallow aquifer shows higher contamination levels, particularly with elevated nitrate concentrations. In the phosphate basin, both washing phosphate and phosphogypsum reveal high levels of radioactive elements, with the latter showing especially high concentrations of radium. The shallow aquifer in this region has moderate contamination levels, while the deep geothermal aquifer also shows noticeable contamination but to a lesser degree compared to the shallow aquifer. The shallow groundwater is characterized by a higher value of radioactivity than the groundwater due to the contamination impact from the phosphate industry and the cumulative radioactivity disintegration. Finally, the nanoparticles and the electrostatic adsorption can decrease the PTEs and radionuclides from the contaminated water in the study area. Moreover, other key issues for advancing research on groundwater contamination are proposed in this study. It is time to valorize this PG and the other mines of (Fe, Pb, and Zn) in the socioeconomic sector in Tunisia and to minimize the environmental impact of the industrial sector’s extraction on groundwater and human health in the study area.

Published

2024

4. Study on the Properties of Waste Apatite Phosphogypsum as a Raw Material of Prospective Applications.

Author

Grabas, Kazimierz, Pawełczyk, Adam, Stręk, Wiesław, Szełęg, Eligiusz, and Stręk, Sven

Abstract

This paper presents the results of the study on chemical and the physical properties of waste phosphogypsum (PG) of apatite origin from the former chemical plant Wizow, Poland which are important for further processing and economic use. The research was carried out to verify whether the waste might be useful as a raw material for rare earth elements (REE) recovery and the manufacture of building materials. The following methods were chosen: X-ray diffraction, scanning electron microscopy with an energy-dispersive X-ray detector, atomic absorption spectrometry, inductively coupled plasma spectrometry, differential thermal analysis, thermogravimetry, and gamma spectrometry with natural radioactive contamination analyzer. It has been proven that the chemical physical properties of phosphogypsum provide an opportunity to utilize this waste material as a source of REE and raw material for building purposes. PG contains an overall amount of REE in the interval of 0.343–0.637% by mass and does not show radioactivity level which would exclude it from construction purposes. The presented results serve as the basis for currently available technological directions in the management of apatite PG for useful trade products, which creates a chance for the elimination of its storage necessity by further processing. [ABSTRACT FROM AUTHOR]

Published

2019

5. Study on the Properties of Waste Apatite Phosphogypsum as a Raw Material of Prospective Applications

Author

Sven Stręk, Wieslaw Strek, Kazimierz Grabas, Adam Pawełczyk, and Eligiusz Szełęg

Subjects

0106 biological sciences, phosphogypsum contamination, Environmental Engineering, 020209 energy, rare earth elements, Phosphogypsum, Chemical plant, 02 engineering and technology, Raw material, Mass spectrometry, 01 natural sciences, Apatite, law.invention, law, 010608 biotechnology, 0202 electrical engineering, electronic engineering, information engineering, morphological characterization, waste, Waste Management and Disposal, Waste management, Renewable Energy, Sustainability and the Environment, Thermogravimetry, visual_art, visual_art.visual_art_medium, Environmental science, Inductively coupled plasma, phosphogypsum, Atomic absorption spectroscopy

Abstract

Waste and Biomass Valorization, Vol. 0, iss. 0 (2018) (online first), This paper presents the results of the study on chemical and the physical properties of waste phosphogypsum (PG) of apatite origin from the former chemical plant Wizow, Poland which are important for further processing and economic use. The research was carried out to verify whether the waste might be useful as a raw material for rare earth elements (REE) recovery and the manufacture of building materials. The following methods were chosen: X-ray diffraction, scanning electron microscopy with an energy-dispersive X-ray detector, atomic absorption spectrometry, inductively coupled plasma spectrometry, differential thermal analysis, thermogravimetry, and gamma spectrometry with natural radioactive contamination analyzer. It has been proven that the chemical physical properties of phosphogypsum provide an opportunity to utilize this waste material as a source of REE and raw material for building purposes. PG contains an overall amount of REE in the interval of 0.343–0.637% by mass and does not show radioactivity level which would exclude it from construction purposes. The presented results serve as the basis for currently available technological directions in the management of apatite PG for useful trade products, which creates a chance for the elimination of its storage necessity by further processing.

Published

2018

6. Rare Earth Element and Radionuclide Distribution in Surface Sediments Along an Estuarine System Affected by Fertilizer Industry Contamination.

Author

Sanders, L., Luiz-Silva, W., Machado, W., Sanders, C., Marotta, H., Enrich-Prast, A., Bosco-Santos, A., Boden, A., Silva-Filho, E., Santos, I., and Patchineelam, S.

Subjects

FERTILIZER industry, RADIOISOTOPES, SEDIMENTATION & deposition, ESTUARY hydrodynamics, INDUSTRIAL contamination, TRACE elements

Abstract

Site-specific contamination related to fertilizer industry activity was demonstrated by light rare earth element (REE) anomalies (sum of La, Ce, Pr, Nd, Sm, and Eu concentrations up to 4.141 mg kg) and radionuclides (Pb and Ra activities up to 994 and 498 Bq kg, respectively) from industrial contamination, within a subtropical estuary (SE Brazil). Anthropogenic influence was also supported by the site-specific Pb and Ra distribution down the estuarine system. The distribution of REE and radionuclide contamination varied along the estuary, which reflected differing sedimentation patterns of phosphogypsum and/or phosphate ore pollutants as identified downstream from the source, likely influenced by sediment-hydrodynamic processes within the estuarine system. Redox- and ion exchange-sensitive pollutants are mobile at the fresh-sea water interface causing an uneven distribution of the pollutants, indicating that the phosphgypsum and/or phosphate ore pollutant deposition can be also influenced by physical and/or geochemical processes associated to estuarine systems. [ABSTRACT FROM AUTHOR]

Published

2013

7. Distribution of rare earth elements in marine sediments from the Strait of Sicily (western Mediterranean Sea): Evidence of phosphogypsum waste contamination.

Author

Tranchida, G., Oliveri, E., Angelone, M., Bellanca, A., Censi, P., D’Elia, M., Neri, R., Placenti, F., Sprovieri, M., and Mazzola, S.

Subjects

RARE earth metals, MARINE sediments, PHOSPHOGYPSUM, YTTRIUM, THORIUM, SCANDIUM

Abstract

Abstract: Concentrations of rare earth elements (REE), Y, Th and Sc were recently determined in marine sediments collected using a box corer along two onshore–offshore transects located in the Strait of Sicily (Mediterranean Sea). The REE+Y were enriched in offshore fine-grained sediments where clay minerals are abundant, whereas the REE+Y contents were lower in onshore coarse-grained sediments with high carbonate fractions. Considering this distribution trend, the onshore sediments in front of the southwestern Sicilian coast represent an anomaly with high REE+Y concentrations (mean value 163.4μgg−1) associated to high Th concentrations (mean value 7.9μgg−1). Plot of shale-normalized REE+Y data of these coastal sediments showed Middle REE enrichments relative to Light REE and Heavy REE, manifested by a convexity around Sm–Gd–Eu elements. These anomalies in the fractionation patterns of the coastal sediments were attributed to phosphogypsum-contaminated effluents from an industrial plant, located in the southern Sicilian coast. [ABSTRACT FROM AUTHOR]

Published

2011

8. Impact of elevated phosphogypsum on soil fertility and its aerobic biotransformation through indigenous microorganisms (IMO's) based technology.

Author

Sengupta, Indraneel and Dhal, Paltu Kumar

Subjects

*BIOCONVERSION, *SOIL fertility, *PHOSPHOGYPSUM, *PHOSPHATE fertilizers, *MICROBIAL remediation, *SOIL amendments, *GYPSUM

Abstract

Phosphogypsum (PG) is a waste by-product of phosphate fertilizer industry, produced in huge amount during the manufacture of phosphoric acid by economic wet process. Assessment of PG toxicity on soil has been poorly emphasized, therefore an efficient methods needs to be adopted to assess its toxic effect on soil fertility. We also need an effective eco-technological strategies for better waste PG management in order to improve the environmental health. The present study aimed to investigate the impact of PG toxicity on fertile soil and utilization of indigenous microorganisms for aerobic detoxification of PG contaminated soil to evaluate the scope for biostimulation based in situ bioremediation. In this study it is evident that application of PG to fertile soil in certain concentration results highly acidic, sulfate rich, aerobic environment, thus severely weakens the metabolic activity of the indigenous microorganisms. This investigation via microcosm based study further evaluated the intrinsic biotransformation ability of these microorganisms and found that was enhanced significantly (>95% reduction in sulfate concentration in 180 days) with carbon, nitrogen and phosphate amendments. Community level physiological profiling analyses indicated distinct shift in metabolic abilities following carbon amendments. Our study for the first time may help to formulate a strategy in aerobic biotransformation of PG contaminated soil environment, yet appreciable rate by supplying adequate nutrients. [Display omitted] • PG reduces AMR profile and alter physicochemical characteristics of fertile soil. • Biostimulation of indigenous microbial community for bioremediation the PG. • Biotechnology for aerobic bioremediation of PG using nutrient amendments. [ABSTRACT FROM AUTHOR]

Published

2021

9. Distribution of rare earth elements in marine sediments from the Strait of Sicily (western Mediterranean Sea): Evidence of phosphogypsum waste contamination

Author

Rodolfo Neri, Paolo Censi, Elvira Oliveri, S. Mazzola, Adriana Bellanca, Giorgio Tranchida, M. D’Elia, Mario Sprovieri, Francesco Placenti, Massimo Angelone, Tranchida, G, Oliveri, E, Angelone, M, Bellanca, A, Censi, P, D’Elia, M, Neri, R, Placenti, F, Sprovieri, M, and Mazzola, S

Subjects

Phosphogypsum contamination, Geologic Sediments, Phosphogypsum, Fractionation, Aquatic Science, Oceanography, Calcium Sulfate, Marine sediments, chemistry.chemical_compound, Mediterranean sea, Mediterranean Sea, Seawater, Transect, Rare earth elements, Rare earth elements Marine sediments Phosphogypsum contamination Strait of Sicily, Phosphorus, Pollution, language.human_language, Settore GEO/08 - Geochimica E Vulcanologia, Strait of Sicily, chemistry, language, Box corer, Carbonate, Metals, Rare Earth, Clay minerals, Sicilian, Water Pollutants, Chemical, Geology, Environmental Monitoring

Abstract

Concentrations of rare earth elements (REE), Y, Th and Sc were recently determined in marine sediments collected using a box corer along two onshore–offshore transects located in the Strait of Sicily (Mediterranean Sea). The REE + Y were enriched in offshore fine-grained sediments where clay minerals are abundant, whereas the REE + Y contents were lower in onshore coarse-grained sediments with high carbonate fractions. Considering this distribution trend, the onshore sediments in front of the southwestern Sicilian coast represent an anomaly with high REE + Y concentrations (mean value 163.4 lg g 1) associated to high Th concentrations (mean value 7.9 lg g 1). Plot of shale-normalized REE + Y data of these coastal sediments showed Middle REE enrichments relative to Light REE and Heavy REE, manifested by a convexity around Sm–Gd–Eu elements. These anomalies in the fractionation patterns of the coastal sediments were attributed to phosphogypsum-contaminated effluents from an industrial plant, located in the southern Sicilian coast.

Published

2011

10. Distribution of rare earth elements in marine sediments from the Strait of Sicily (western Mediterranean Sea): Evidence of phosphogypsum

Author

Tranchida G., Oliveri E., Angelone M., Bellanca A., Censi P., D’Elia M., Neri R., Placenti F., Sprovieri M., and Mazzola S.

Subjects

Phosphogypsum contamination, Strait of Sicily, Marine sediments, Rare earth elements

Published

2011