Fate and Toxicity of Spilled Chemicals in Groundwater and Soil Environment II: Flammable
Jho, Eun Hea;Shin, Doyun;
Department of Environmental Science, Hankuk University of Foreign Studies (HUFS);Mineral Resources Research Division, Korea Institute of Geoscience and Mineral Resources (KIGAM);
사고 누출 화학물질의 지하수 및 토양 환경 내 거동 및 환경 독성 특성 II: 인화성 물질을 중심으로
조은혜;신도연;
한국외국어대학교 환경학과;한국지질자원연구원 광물자원연구본부;

Abstract

In this study, formaldehyde and benzene were selected as the arbitrary chemicals in accidental leakage to environment, and their physicochemical and biological characteristics and toxicity were studied. Also, the fate of these chemicals in soil and groundwater was studied based on the results of previous studies. They can be released into the atmosphere as gas or vapor phase, which then can be photochemically degraded. Since they have relatively high water solubility, they are likely to have high mobility in water and soil. Volatilization of these chemicals from soil is affected by the soil moisture content. Biodegradation of formaldehyde and benzene is one of the important pathways as well. Therefore, it is necessary to study the environmental impacts of leakage accidents of flammable chemicals such as formaldehyde and benzene. Further research on the fate of flammable chemicals in the environment is needed to take appropriate response actions to leakage accidents of flammable chemicals, and this will contribute to the development of practical guidelines to cope with leakage accidents.

Keywords: Flammable chemicals;Formaldehyde;Formalin;Benzene;Chemical spill;

References

1. Anderson, T.A., Beauchamp, J.J., and Walton, B.T., 1991, Fate of volatile and semivolatile organic chemicals in soils: Abiotic versus biotic losses, J. Environ. Qual., 20(2), 420-424.
2. Atkinson R, 1994, Gas-phase tropospheric chemistry of organic compounds: a review, J. Phys. Chem. Ref. Data., Monograph No. 2, 1-216.
3. Atkinson, R., Baulch, D.L., Cox, R.A., Crowley, J.N., Hampson, R.F., Hynes, R.G., Jenkin, M.E., Rossi, M.J., Troe, J., and Subcommittee, I.U.P.A.C., 2006, Evaluated kinetic and photochemical data for atmospheric chemistry: Volume II-gas phase reactions of organic species, Atmos. chem. Phys., 6(11), 3625-4055.
4. Baek, D.S., Park, C.H., Kim, D.J., Kim, H.S., Lee, H.W., and Park, Y.K., 2001, Transport and Degradation of Benzene affected by Hydrogen Peroxide and Microorganism in a Sandy Soil, J. Soil Groundw. Environ., 6(2), 49-56.
5. Bekins, B.A., Cozzarelli, I.M., Erickson, M.L., Steenson, R.A., and Thorn, K.A., 2016, Crude oil metabolites in groundwater at two spill sites, Groundwater, 54(5), 681-691.
6. Betterton, E.A. and Hoffmann, M.R., 1988, Henry's law constants of some environmentally important aldehydes, Environ. Sci. Technol., 22(12), 1415-1418.
7. Boubik, T., Fried, V., and Hala, E., 1984, The vapour pressures of pure substances, Vol. 17. Elsevier Science Publishing Company, Inc., Amsterdam, The Netherlands
8. Buxton, G.V., Greenstock, C.L., Helman, W.P., and Ross, A.B., 1988, Critical review of rate constants for reactions of hydrated electrons, hydrogen atoms and hydroxyl radicals (OH/O in aqueous solution, J. Phys. Chem. Ref. Data, 17(2), 513-886.
9. Cho, S.J. and Ahn, D.H., 2006, Characteristics of Adsorption and Movement of Benzene, Phenol, 2,4-DCP in Soil, J. Korea Soc. Environ. Administ., 9, 165-170.
10. Choi, J.W., 2004, Effect of PAC on sorption desorption kinetics of benzene, Master dissertation at Korea University.
11. Cooke, C.M., Bailey, N.J., Shaw, G., Lester, J.N., and Collins, C.D., 2003, Interaction of formaldehyde with soil humic substances: separation by gfc and characterization by 1 H-NMR spectroscopy, Bull. Environ. Contam. Toxicol., 70(4), 761-768.
12. Daubert, T.E. and Danner, R.P., 1989, Physical and thermodynamic properties of pure chemicals data compilation, Taylor and Francis., Washington, D.C..
13. De, S.K. and Chandra, K., 1978, Adsorption of formaldehyde by Indian clay minerals, Sci. Cult., 44, 462-464.
14. Gerberich H.R. and Seaman G.C., 2013, Formaldeyde. Kirk-Othmer Encyclopedia of Chemical Technology, Online Posting Date: Jan 18, 2013. John Wiley & Sons, New York, NY.
15. Grbic-Galic, D., 1990, Methanogenic transformation of aromatic hydrocarbons and phenols in groundwater aquifers, Geomicrobiol. J., 8(3-4), 167-200.
16. Han, T.I., Moon, J.Y., Hwang, Y.W., and Cheon, Y.W., 2016, 불산 및 벤젠 실내 저장시설에서의 소량누출에 따른 피해 영향범위 선정에 관한 연구, Korea Soc. Ind., Eng. Chem., 369-369.
17. Hansch, C., Leo, A., Hoekman, D., and Livingstone, D.J., 1995, Exploring QSAR: hydrophobic, electronic, and steric constants, Vol. 48, American Chemical Society, Washington, DC.
18. Haider, K., Jagnow, G., Kohnen, R., and Lim, S.U., 1974, Degradation of chlorinated benzenes, phenols and cyclohexane derivatives by benzene and phenol utilizing soil bacteria under aerobic conditions, Arch. Microbiol., 96(3), 183-200.
19. Hodson, J. and Williams, N.A., 1988, The estimation of the adsorption coefficient (Koc) for soils by high performance liquid chromatography, Chemosphere, 17(1), 67-77.
20. Howard, P., Durkin, P.R., and Schuth, C., 1974, Benzene: Environmental Sources of Contamination, Ambient Levels, and Fate - Final Report - Task One. USEPA-560/5-75-005. Office of Toxic Substances, US Environmental Protection Agency, Washington, D.C.
21. Hustert, K., Mansour, M., Parlar, H., and Korte, F., 1981, Der EPA-Test-eine Methode zur Bestimmung des photochemischen Abbaus von organischen Verbindungen in aquatischen Systemen, Chemosphere, 10(9), 995-998.
22. Hutchins, S.R. and Wilson, J.T., 1991, Laboratory and field studies on BTEX biodegradation in a fuel-contaminated aquifer under denitrifying conditions, In: Hinchee RE, Olfenbuttel RF (ed), In Situ Bioreclamation, Butterworth-Heinemann, Boston, MA, p.157-172
23. IARC, 1992-present, Agents classified by the IARC monographs, https://monographs.iarc.fr/agents-classified-by-the-iarc/, [accessed 18.12.04].
24. Kang, D.H., Chung, S.Y., and Go, D.H., 2006, The Contamination Characteristics of BTEX and TPH Components in Silty Soils with the Oil Leakage Event from Point Source, J. Eng. Geol., 16(4), 393-402.
25. Kang, S.J., Lee, I.K, Moon, J.Y., and Chon, Y.W., 2017, Risk Analysis of Ammonia Leak in the Refrigeration Manufacturing Facilities, J. Korean Inst. Gas, 21(1), 43-51.
26. Kitchens, J.F., Casner, R.E., Edwards, G.S., Harward, W.E.I.I.I., Macri, B.J., 1976, Investigation of selected potential environmental contaminants: formaldehyde. Available from the National Technical Information Service, Springfield VA 22161 as PB-256 839, US Environmental Protection Agency, Washington, D.C.
27. Kwon, Y.J., 2014, Catalytic and adsorptive degradation of BTEX and diesel compounds by nano-pore ceramic adsorbent, Doctoral dissertation at Hanyang University.
28. Lee, H.C, Kim, H.J., Shin, D., and Kim, T.O., 2004, Consequence Analysis for Accidental Releases of Toxic Gases through Risk Based Inspection using API-581, J. Korean Inst. Gas, 8(4), 8-14.
29. Limmer, M. and Burken, J., 2016, Phytovolatilization of organic contaminants, Environ. Sci. Technol., 50(13), 6632-6643.
30. Lyman, W.J., Reehl, W.F., and Rosenblatt, D.H., 1990, Handbook of chemical property estimation methods: Environmental behavior of organic compounds, American Chemical Society, Washington, D.C.
31. Mackay, D., Shiu, W.Y., and Sutherland, R.P., 1979, Determination of air-water Henry's law constants for hydrophobic pollutants, Environ. Sci. Technol., 13(3), 333-337.
32. MacLeod, M. and Mackay, D., 1999, An assessment of the environmental fate and exposure of benzene and the chlorobenzenes in Canada, Chemosphere, 38(8), 1777-1796.
33. May, W.E., Wasik, S.P., Miller, M.M., Tewari, Y.B., Brown-Thomas, J.M., and Goldberg, R.N., 1983, Solution thermodynamics of some slightly soluble hydrocarbons in water, J. Chem. Eng. Data, 28(2), 197-200.
34. Miller, L.G., Warner, K.L., Baesman, S.M., Oremland, R.S., McDonald, I.R., Radajewski, S., and Murrell, J.C., 2004, Degradation of methyl bromide and methyl chloride in soil microcosms: Use of stable C isotope fractionation and stable isotope probing to identify reactions and the responsible microorganisms, Geochim. Cosmochim. Ac., 68(15), 3271-3283.
35. Nam, K. and Kim, J.Y., 2002, Aging and Bioavailability, and Their Impact on Risk-Based Remedial Endpoint, J. Korean Soc. Environ. Eng., 11, 1975-2000.
36. NCIS (National Chemical Information System), 2018, http://ncis.nier.go.kr/, Formaldehyde. [accessed 18.09.11].
37. Neff, J.M. and Sauer, T.C., 1996, Aromatic hydrocarbons in produced water. In Produced Water 2. Boston, MA: Springer, pp. 163-175
38. Newman, L.A., Doty, S.L., Gery, K.L., Heilman, P.E., Muiznieks, I., Shang, T.Q., Siemieniec, S.T., Strand, S.E., Wang, X., Wilson, A.M., and Gordon, M.P., 1998, Phytoremediation of organic contaminants: a review of phytoremediation research at the University of Washington, J. Soil Contam., 7(4), 531-542.
39. NITE, 2016, Chemical Risk Information Platform (CHRIP). Biodegradation and Bioconcentration Results, National Institute of Technology and Evaluation (NITE), Tokyo, Japan.
40. OECD, 2002, SIDS initial assessment report for SIAM 14, Formaldehyde (CAS No. 50-00-0), http://www.inchem.org/documents/sids/sids/FORMALDEHYDE.pdf, [accessed 18.12.04].
41. Park, K.C. and Kim, B.J., 2000, An Evaluation of the Fire and Explosion Effect by BTX released in a Chemical Plant, J. Korean Inst. Gas, 9, 9-18.
42. Petersen, L.W., Moldrup, P., El-Farhan, Y.H., Jacobsen, O.H., Yamaguchi, T., and Rolston, D.E., 1995, The effect of moisture and soil texture on the adsorption of organic vapors, J. Environ. Qual., 24(4), 752-759.
43. Pickrell, J.A., Mokler, B.V., Griffis, L.C., Hobbs, C.H., and Bathija, A., 1983, Formaldehyde release rate coefficients from selected consumer products, Environ. Sci. Technol., 17(12), 753-757.
44. Reinhard M., Shang, S., Kitanidis, P.K., Orwin, E., Hopkins, G.D., Blier, H.R., and LeBron, C.A., 1996, In situ BTEX biotransformation under intrinsic and nitrate- and sulfate-reducing conditions, the 211th American Chemical Society National Meeting, Amerian Chemical Society, New Orleans, Louisiana, March 24-28, 37(1), 210-212.
45. Rodin, I.A., Moskvin, D.N., Smolenkov, A.D., and Shpigun, O.A., 2008, Transformations of asymmetric dimethylhydrazine in soils, Russ. J. Phys. Chem. A+, 82(6), 911-915.
46. Sengor, S.S. and Unlu, K., 2013, Modeling contaminant transport and remediation at an acrylonitrile spill site in Turkey, J. Contam. Hydrol., 150, 77-92.
47. Shin, D., Kim, Y., and Moon, H.S., 2018, Factors on fate and toxicity of strong acids in groundwater and soil environment, Environ. Health Toxicol., in press.
48. Su, F., Calvert, J.G., and Shaw, J.H., 1979, Mechanism of the photooxidation of gaseous formaldehyde, J. Phys. Chem., 83(25), 3185-3191.
49. TOXNET (Toxicology Data Network), 2018, Formaldehyde. https://toxnet.nlm.nih.gov/cgi-bin/sis/search2/f?./temp/-PJqFh7:1, [accessed 18.09.11].
50. Trost, B., Stutz, J., and Platt, U., 1997, UV-absorption cross sections of a series of monocyclic aromatic compounds, Atmos. Environ., 31(23), 3999-4008.
51. US DHHS (US Department of Health and Human Services), 2016, 14th Report on carcinogens, https://ntp.niehs.nih.gov/pubhealth/roc/index-1.html#toc1. [accessed 18.08.02].
52. US EPA, 2008, Reregistration Eligibility Decision for formaldehyde and paraformaldehyde (Case 0556). EPA 739-R-08-004, https://archive.epa.gov/pesticides/reregistration/web/pdf/formaldehyde-red.pdf, [accessed 18.08.03].
53. US EPA, 2012, EPI $Suite^{TM}$ - Estimation Program Interface. Ver. 4.11., https://www.epa.gov/tsca-screening-tools/epi-suitetm-estimation-program-interface, [accessed 18.08.02].
54. Verschueren, K., 2001, Handbook of environmental data on organic chemicals: Vol. 1 (No. Ed. 4). John Wiley and Sons, Inc., New York, NY.
55. Wilson, J.T., Adair, C., White, H., and Howard, R.L., 2016, Effect of biofuels on biodegradation of benzene and toluene at gasoline spill sites, Groundwater Monit. R., 36(4), 50-61.
56. Wilson, M.A., Burt, R., Indorante, S.J., Jenkins, A.B., Chiaretti, J.V., Ulmer, M.G., and Scheyer, J.M., 2008, Geochemistry in the modern soil survey program, Environ. Monit. Assess., 139(1-3), 151-171.
57. Zhang, W.X. and Bouwer, E.J., 1997, Biodegradation of benzene, toluene and naphthalene in soil-water slurry microcosms, Biodegradation, 8(3), 167-175.

This Article

2018; 23(6): 1-8

Published on Dec 31, 2018
10.7857/JSGE.2018.23.6.001
Received on Oct 5, 2018
Accepted on Nov 12, 2018

This Article

Services

Shared