Environmental Remediation of Oil Contaminated Soil

Author(s):  
A. Nishida ◽  
Aparna Gopinath ◽  
S. Chandraj ◽  
K. Radhika ◽  
R. Sethu
Author(s):  
Ondrej Slavik ◽  
Miroslav Baca ◽  
Alojz Slaninka ◽  
Stanislav Janecka ◽  
Ja´n Sirota

Environmental remediation at NPP A1 site is even presently a continual process of removing the contamination from the ground or auxuliary objects within the NPP A-1 site with accidentally shut down reactor. This paper mainly deal with monitoring, sorting out and disposal of large volumes of removed contaminated soil stored temporarily until now at the site which is necessary for enhancement of environmental radiation situation at the site. It was also one of the topic of the Decommissioning Project of NPP A1, Slovakia, - Phase No I, lasted from 1999 to 2008. Within the project, attention was paid to development of technical tools for handling with and monitoring of large volume of contaminated soil, as well. Besides short description of contaminated lands at the site, sources of their contamination and to date known inventory, details of a pilot contaminated soil sorting facility developed and tested recently within the Decommissioning project will be described and discussed in the papper. The paper topics include description of and uncertainty analysis results for the pilot soil sorting system based on the Canberra-Packard pilot conveyer belt monitor with a pair of 1.5 inch LaBr scintilation detectors and integrated electronic belt scale. In addition experiences learned during the metrological testing and operational trial will be summarised. MDA for Cs-137 of this system is 140 Bq/kg for 30 kg and 50 Bq/kg for 300 kg parts of soil at 500 Bq/kg of 40K and 0.15 mikroGy/h.


Processes ◽  
2021 ◽  
Vol 9 (9) ◽  
pp. 1606
Author(s):  
Prisha Mandree ◽  
Wendy Masika ◽  
Justin Naicker ◽  
Ghaneshree Moonsamy ◽  
Santosh Ramchuran ◽  
...  

Polycyclic aromatic hydrocarbons (PAHs) are reportedly toxic, ubiquitous and organic compounds that can persist in the environment and are released largely due to the incomplete combustion of fossil fuel. There is a range of microorganisms that are capable of degrading low molecular weight PAHs, such as naphthalene; however, fewer were reported to degrade higher molecular weight PAHs. Bacillus spp. has shown to be effective in neutralizing polluted streams containing hydrocarbons. Following the growing regulatory requirement to meet the PAH specification upon disposal of contaminated soil, the following study aimed to identify potential Bacillus strains that could effectively remediate low and high molecular weight PAHs from the soil. Six potential hydrocarbon-degrading strains were formulated into two prototypes and tested for the ability to remove PAHs from industry-contaminated soil. Following the dosing of each respective soil system with prototypes 1 and 2, the samples were analyzed for PAH concentration over 11 weeks against an un-augmented control system. After 11 weeks, the control system indicated the presence of naphthalene (3.11 µg·kg−1), phenanthrene (24.47 µg·kg−1), fluoranthene (17.80 µg·kg−1) and pyrene (28.92 µg·kg−1), which illustrated the recalcitrant nature of aromatic hydrocarbons. The soil system dosed with prototype 2 was capable of completely degrading (100%) naphthalene, phenanthrene and pyrene over the experimental period. However, the accumulation of PAHs, namely phenanthrene, fluoranthene and pyrene, were observed using prototype 1. The results showed that prototype 2, consisting of a combination of Bacillus cereus and Bacillus subtilis strains, was more effective in the biodegradation of PAHs and intermediate products. Furthermore, the bio-augmented system dosed with prototype 2 showed an improvement in the overall degradation (10–50%) of PAHs, naphthalene, phenanthrene and pyrene, over the un-augmented control system. The following study demonstrates the potential of using Bacillus spp. in a bioremediation solution for sites contaminated with PAHs and informs the use of biological additives for large-scale environmental remediation.


Catalysts ◽  
2021 ◽  
Vol 11 (3) ◽  
pp. 331
Author(s):  
Muhammad Usman ◽  
Olivier Monfort ◽  
Stefan Haderlein ◽  
Khalil Hanna

Development of new tools to improve the efficiency of iron minerals in promoting Fenton oxidation for environmental remediation is a highly promising field. Here, we examine for the first time the role of ascorbic acid (AA) in improving the magnetite (Fe3O4)-mediated Fenton oxidation to remove pentachlorophenol (PCP) in a historically contaminated soil. Experiments were performed in batch and flow-through conditions. In batch slurry experiments, the combination of Fe3O4/AA/H2O2 removed up to 95% of PCP as compared to the 43% removal by Fe3O4/H2O2. Dissolved Fe(II) measurements and Mössbauer spectroscopy highlight the role of AA in increasing the Fe(II) generation. Therefore, its presence enabled the Fe3O4 to maintain its structural Fe(II) content even after the oxidation reaction. Despite kinetic limitations in water-saturated columns, use of Fe3O4/AA/H2O2 removed about 70% of PCP contrary to the 20% PCP removal with Fe3O4/H2O2. This oxidation performance was affected by an injection flow rate or column residence time of AA and H2O2 in columns. Thus, the presence of AA significantly improved the ability of magnetite in promoting the Fenton reaction. Owing to the crucial role of AA in the Fe(II)/Fe(III) redox cycling, a mixed-valent character of magnetite makes it a potential catalyst for Fenton oxidation of organic pollutants.


Pollutants ◽  
2021 ◽  
Vol 1 (3) ◽  
pp. 119-126
Author(s):  
Nnanake-Abasi O. Offiong ◽  
Edu J. Inam ◽  
Helen S. Etuk ◽  
Godwin A. Ebong ◽  
Akwaowo I. Inyangudoh ◽  
...  

Biochar utilization for environmental remediation applications has become very popular. We investigated the trace metal levels and soil nutrient characteristics of a biochar–humus sediment slurry treatment of a simulated crude oil-contaminated soil in the present work. The results revealed that biochar prepared at moderate pyrolysis temperature (500 °C) could still retain a significantly higher nutrient content than those prepared at high temperatures (700 and 900 °C). Despite the suitability for soil treatment, one-pot treatment studies seem not to be very effective for monitoring trace metal sorption to biochar because trace metals do not biodegrade and remain in the system.


2013 ◽  
Vol 4 (8) ◽  
pp. 3184 ◽  
Author(s):  
Wei Jiang ◽  
Shenliang Wang ◽  
Lik Hang Yuen ◽  
Hyukin Kwon ◽  
Toshikazu Ono ◽  
...  

2021 ◽  
Author(s):  
Yu Xiaoyan ◽  
Wei Guangpu ◽  
Song Yuchen ◽  
Kang Yu

Abstract In order to repair light rare earth soil effectively, plant and mycorrhizae technology were applied together. It will provide theoretical basis for ecological restoration of light rare earth contaminated soil. The method of greenhouse pot experiment was used in this study. The concentrations of lanthanum (La) in tested soil samples were 107.15, 329.41, and 2,031.71 mg/kg and cerium (Ce) were 362.11, 741.81, 4,162.03 mg/kg. The ectomycorrhiza (Boletus luridus Schaeff.(BLS),Inocybe lilacina(Boud.)Kauffm.(ILK)༌Russula foetens(Pers.)Pers.(RFP)༌Lactarius sanguifluus (Paul.) Fr.(LSF)) was inoculated on Pinus tabuliformis. The inoculation rate and biomass of mycorrhiza, as well as the absorption, transfer and root retention of La and Ce, light rare earth elements (LREE) by plants were determined to provide the theoretical basis for the treatment of La and Ce contaminated soil. The results showed that a symbiotic relationship was established between ectomycorrhiza and Pinus tabuliformis. The mycorrhizal infection rate of Pinus tabulaeformis ranged from 0.51–64.81%, The biomass results showed that the dry weight of aboveground organs and roots increased by 1.46, 1.67 and 1.88 times, 1.73, 1.98 and 2.08 times, respectively. With the increase of the concentration of La and Ce in the soil, the increase of one LREE in the host plants inoculated with mycorrhizae was greater than that in the blank control group. Following mycorrhizal inoculation, La and Ce transfer coefficients in P. and root retention coefficients increased, which may lead to the decrease of absorption and transfer capacity of hyperaccumulators. This study showed that mycorrhizae can improve the absorption of La and Ce by host plants, demonstrating potential value in the environmental remediation of LREE contaminated soil.


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