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  • P-ISSN1225-0163
  • E-ISSN2288-8985
  • SCOPUS, ESCI, KCI

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  • P-ISSN 1225-0163
  • E-ISSN 2288-8985

퇴적물 중 브롬화난연제 농도분포 특성에 관한 연구

Study on distribution characteristics of brominated flame retardants in sediments

분석과학 / Analytical Science and Technology, (P)1225-0163; (E)2288-8985
2012, v.25 no.4, pp.242-249
https://doi.org/10.5806/AST.2012.25.4.242
김태승 (국립환경연구원)
신선경 (국립환경과학원)
오정근 (요코하마대학)
박종은 (전북대학교)
  • 다운로드 수
  • 조회수

초록

본 연구에서는 퇴적물 중 브롬화난연제의 잔류농도 분포특성을 파악하기 위해 금강과 낙동강 수계 및 하구언에서 총 11개 시료를 대상으로 PBDEs와 HBCD를 분석하였다. PBDEs의 총 농도 검출범위는 2.19~101.34 ng/g-dw, 평균농도는 30.70 (중앙값 20.91) ng/g-dw로 나타났으며 하천이 하구언에 비해농도변화가 큰 것으로 나타났다. HBCD 농도범위는 N.D.~7.85 ng/g-dw, 평균농도는 1.47 (중앙값 0.34)ng/g-dw로 나타났다. HBCD 농도는 PBDEs에 비해 약 1/20 정도 낮은 범위로서 이는 국내에서 사용된브롬화 난연제 중 HBCD 사용량이 상대적으로 적었기 때문인 것으로 판단된다. PBDEs와 HBCD의 이성체 분포를 확인한 결과, 상업용 제품사용에 의한 유출과 같은 직접적인 원인 외에도 이들 물질의 물리화학적 성질과 광학적 분해 및 환경 중 거동 특성 등이 복합적으로 작용하여 분포패턴에 영향을 미치는것으로 판단되었다.

keywords
BFRs, PBDEs, HBCD, sediment, distribution

Abstract

Total 11 samples of sediments from the Geum river and the Nakdong river and its estuaries were analyzed to investigate the distribution characteristics of PBDEs and HBCD. Concentration of PBDEs in sediments ranged from 2.19~101.34 (average 30.70, median 20.91) ng/g-dw. The concentration range of PBDEs in river sediments is greater than those of estuary sediments. The HBCD concentration was ranged from N.D.~7.85 (average 1.47,median 0.32) ng/g-dw. HBCD concentrations compared with PBDEs are approximately 1/20 level, which is associated with low domestic usage. Isomer patterns of PBDEs and HBCD suggested that not only the use of commercial products, but the physicochemical properties of these materials, environmental degradation, and environmental behavior could affect the distribution characteristics of these chemicals and their isomers.

keywords
BFRs, PBDEs, HBCD, sediment, distribution


참고문헌

1

1. Cheri Peele, ‘Washington state PBDE chemical action plan’, Washington state department of ecology, 17-20, 2004.

2

2. Ann Blake, Ph, D, The next generation of POPs : PBDEs and Lindane, International POPs Elimination Network, 3, 2005.

3

3. K. Nylund, L. Asplund, B. Janssen, P. Jonsson, K. Litzen and U. Sellström, Chemosphere, 24, 1721-1730 (1992).

4

4. N. H. Minh, Y. Isobe, D. Ueno, K. Matsumoto, M. Mine, N. Kajiwara, S. Takahashi and S. Tanabe, Environ. Pollution., 148, 409-417 (2007).

5

5. D. Meironyté, Å. Bergman and K. Norén, Arch. Environ. Contam. Toxicol., 40, 564-570 (2001).

6

6. Korea Environment Institite, ‘Management of contaminated sediments from lake and river’, 1998.

7

7. Environment Ministry of Japan, ‘Information on survey of chemicals’, 2009.

8

8. National Institute of Environmental Research, ‘Survey on temporal and spatial distribution in environment of NEW POPs(II)’, 2011.

9

9. H.-H. Kang, ‘Spatial distribution of brominated flame retardants in surface sediment of the Nakdong River in Korea Domestic’ Master Thesis, Busan National University, 2011.

10

10. S. U. We, J. H. Yoon and N. W. Min, Environ. Eng. Res., 32(5), 427-436 (2010).

11

11. K. Ramu, T. Isobe, S. Takahashi, E.-Y. Kim, B.-Y. Min and S-U We, Chemosphere, 79(7), 713-719 (2010).

12

12. W. Song, A. Li, J. C. Ford, N. C. Sturchio, K. J. Rockne, D. R. Buckley and W. J. Mills, Environ. Sci. Technol., 39, 5600-5605 (2005).

13

13. N. H. Minh, T. Isobe, D. Ueno, K. Matsumoto, M. Mine, N. Kajiwara, S. Takahashi and S. Tanabe, Environ. Pollut., 148, 409-17 (2007).

14

14. E. Eljarrat, D. Larrazabal, B. Fabrellas, A. R. Fernandez-Alba, F. Borrull, R. M. Marce and D. Barcelo, Environ. Pollut., 136(3), 493-501 (2005).

15

15. S. J. Chen, X. J. Gao, B. X. Mai, Z. M. Chen, X. J. Luo, G. Y. Sheng, J. M. Fu and E. Y. Zeng, Environ. Pollut., 144, 951-957 (2006).

16

16. T. A. Verslycke, A. D. Vethaak, K. Arijs and C. R. Janssen, Environ. Pollut., 136, 19-31 (2005).

17

17. B. X. Mai, S. J. Chen, X. J. Luo, L. G. Chen, Q.S. Yang, G. Y. Peng, J. M. Fu and E. Y. Zeng, Environ. Sci. Technol., 39, 3521-3527 (2005).

18

18. C. H. Marvin, G. T. Tomy, M. Alaee and G. Macinnis, Chemosphere, 64(2), 268-759 (2006).

19

19. H. Stuart, A. A Mohamed, L. R. Neil, D. Simon and T. A. Davidson, Environ. Sci. Technol, 43(24), 9077-9083 (2009).

20

20. P. Guerra, A. De La Cala, G. Marsha, E. Eljarrata and D. Barceló, J. Hydrol., 369, 360-367 (2009).

21

21. S. Managaki, I. Enomoto and S. Masunaga, Environ Monitor, 14(3), 901-977 (2012).

22

22. S. Thorsten, K. Andrea, R. Matthias, S. George, W.-S. Evelyn and L. Peter, Organohalogen Compounds, 70, 1590-1593 (2008).

23

23. H. Li, H. Shang, P. Wang, Y. Wang, H. Zhang, Q. Zhang and G. Jiang. J. Environ. Sci., 24, in press (2012).

24

24. Cischem, ‘Status report on domestic and foreign markets, and environmental regulations of BFRs’, 2009.

25

25. MARK J. LA GUARDIA, ROBERT C. HALE and ELLEN HARVEY., Environ. Sci. Technol, 40, 6247-6254 (2006).

26

26. V. H. Norbert, W. B. Schweiz, M. Kohler and A. C. Gerecke, Chemosphere, 61, 65-73 (2005).

27

27. M. Peled, R. Scharia and D. Sondack, In ‘Advances in Organobromine Chemistry II’, p.92-99, Elsevier, Amsterdam, 1995.

28

28. A. C. Gerecke, W. Giger, P. C. Hartmann, N. V. Heeb, H. E. Kohler, P. Schmid, M. Zennegg and M. Kohler, Chemosphere, 64, 311-317 (2006).

29

29. Environment Ministry of Japan, Studies on Material Cycles and Waste Management, 2011.

30

30. Juan Bezares-Cruz, Chadt. Jafvert and Inezhua, Environ. Sci. Technol. 38, 4149-4156 (2004).

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