- citati u SCIndeksu: [1]
- citati u CrossRef-u:[1]
- citati u Google Scholaru:[]
- posete u poslednjih 30 dana:5
- preuzimanja u poslednjih 30 dana:5
|
|
2016, vol. 57, br. 3, str. 389-396
|
Monitoring podzemnih voda - neophodan korak u utvrđivanju načina sanacije kontaminiranog lokaliteta
Monitoring of underground water: Necessary step in determining the method for site remediation
aUniverzitet u Beogradu, Institut za hemiju, tehnologiju i metalurgiju - IHTM, Srbija bUniverzitet u Beogradu, Hemijski fakultet, Srbija cUniverzitet u Beogradu, Rudarsko-geološki fakultet, Srbija
e-adresa: javdalovic@chem.bg.ac.rs
Projekat: Simultana bioremedijacija i soilifikacija degradiranih prostora, za očuvanje prirodnih resursa biološki aktivnih supstanci i razvoj i proizvodnju biomaterijala i dijetetskih proizvoda (MPNTR - 43004)
Sažetak
Predmet ovog istraživanja je ispitivanje kvaliteta podzemnih voda na lokalitetu toplane 'Novi Beograd' (Srbija). Istraživanjima je obuhvaćen sistem od 10 pijezometara (P1, P5, P6, P7, P8, P9, P10, P11, P12, P13), koji su konstruisani u dva ciklusa (P1, P5, P6 i P13 do dubine od 10 metara i od P7 d o P12 do dubine od 15 metara). Dobijeni rezultati pokazuju da je oblast u kojoj se nalaze pijezometri od P5 do P8, kao i P12 i P13, oblast u kojoj je koncentracija ukupnih ugljovodonika nafte veća od remedijacione vrednosti koja je normirana na 0,6 mg/L. Takođe, utvrđeno je da je ukupna zapremina kontaminirane podzemne vode o ko 105.000 m 3. Sve navedeno ukazuje da je neophodno pristupiti sanaciji podzemne vode kontaminirane ugljovodonicima nafte, kao i da je najoptimalniji postupak za navedeni lokalitet in situ bioremedijacija.
Abstract
The object of this study was to investigate the quality of underground water on the location of heating plant 'Novi Beograd' (Serbia). The examination included a system of 10 piezometers (P1, P5, P6, P7, P8, P9, P10, P11, P12, P13), which are constructed in two cycles (P1, P5, P6 and P13 are located at depth of up to 10 m, and P7 to P12 are located at depth of up to 15 m). Obtained results indicate that the area P5 to P8, as well as P12 and P13, has a concentration of total petroleum hydrocarbons greater that the remediation value standardized as 0,6 mg/L. It was also determined that the total volume of the contaminated underground water is around 105.000m3. All of the above indicates that it is necessary to start the remediation of underground water contaminated with petroleum hydrocarbons and that the most appropriate remediation procedure for this site is in situ bioremediation.
|
|
|
Reference
|
|
*** (2000) ISO 9377-2: International standard: Water quality-determination of hydrocarbon oil index: Method using solvent extraction and gas chromatography. Geneva: ISO, Part 2
|
|
*** (1995) How to evaluate alternative cleanup technologies for underground storage tank sites: A guide for corrective action plan reviewers. US: EPA
|
|
*** (2010) The regulation on the programme for the systematic monitoring of soil quality, soil degradation risk assessment indicators and methodology for the development of remediation programmes. RS Official Gazette, No88 (in Serbian)
|
|
Bedient, P., Rifai, H., Newell, C. (1999) Ground water contamination transport and remediation. Upper Saddle: Prentice Hall, 2nd edn
|
1
|
Beškoski, V.P., Gojgić-Cvijović, G., Milić, J., Ilić, M., Miletić, S., Solević, T., Vrvić, M.M. (2011) Ex situ bioremediation of a soil contaminated by mazut (heavy residual fuel oil): A field experiment. Chemosphere, 83(1): 34-40
|
|
Bossert, I.D., Shor, L.M., Kosson, D.S. (2002) Methods for measuring hydrocarbon biodegradation in soils. u: Manual of Environmental Microbiology, Washington: ASM Press, second ed. p. 934-943
|
1
|
Gojgic-Cvijovic, G.D., Milic, J.S., Solevic, T.M., Beskoski, V.P., Ilic, M.V., Djokic, L.S., Narancic, T.M., Vrvic, M.M. (2012) Biodegradation of petroleum sludge and petroleum polluted soil by a bacterial consortium: A laboratory study. Biodegradation, 23(1): 1-14
|
|
Hatzinger, P.B., Whittier, M. C., Arkins, M.D., Bryan, C.W., Guarini, W.J. (2002) In-Situ and Ex-Situ Bioremediation Options for Treating Perchlorate in Groundwater. Remediation Journal, 12(2): 69-86
|
1
|
Ilić, M., Antić, M., Antić, V., Schwarzbauer, J., Vrvić, M., Jovančićević, B. (2011) Investigation of bioremediation potential of zymogenous bacteria and fungi for crude oil degradation. Environmental Chemistry Letters, 9(1): 133-140
|
|
Loser, C., Seidel, H., Zehnsdorf, A., Stottmeister, U. (1998) Microbial degradation of hydrocarbons in soil during aerobic/anaerobic changes and under purely aerobic conditions. Applied Microbiology and Biotechnology, 49(5): 631
|
|
Mackay, D.M., Cherry, J.A. (1989) Groundwater contamination: pump-and-treat remediation. Environmental Science & Technology, 23(6): 630-636
|
|
Marić, N., Ilić, M., Miletić, S., Gojgić-Cvijović, G., Beškoski, V., Vrvić, M.M., Papić, P. (2015) Enhanced in situ bioremediation of groundwater contaminated by petroleum hydrocarbons at the location of the Nitex textiles, Serbia. Environmental Earth Sciences, 74(6): 5211-5219
|
|
Mirsal, I.A. (2008) Soil Pollution - Origin, Monitoring & Remediation. Springer, 2nd Ed
|
|
Polomčić, D., Ristić, V.V. (2011) Groundwater in water supply of Serbia-current state and perspectives. Belgrade: Faculty of Mining and Geology, p. 45-77
|
|
Talley, J.W., Sleeper, P.M. (1997) Roadblocks to the Implementation of Biotreatment Strategies. Annals of the New York Academy of Sciences, 829(1 Bioremediatio): 16-29
|
|
Ugochukwu, U.C., Jones, M.D., Head, I.M., Manning, David. A. C., Fialips, C.I. (2013) Biodegradation of crude oil saturated fraction supported on clays. Biodegradation, 25(1): 153-165
|
|
Vrvić, M., Jovančićević, B., Miletić, S. (2015) Detailed examination of soil contaminated with hydrocarbons petroleum on the location of heating plant (Research of hydrochemical and geochemical processes and geomicrobiological and biogeochemical interaction in groundwater and surface water and soi. in Serbian
|
|
|
|