Browse > Article
http://dx.doi.org/10.5657/kfas.2004.37.4.295

Effect of Environmental Variables on the Inter- and Subtidal Macrobenthic Communities in the Iwon Dike Area  

LEE Jae-Hac (Marine Living Resources Research Division, Korea Ocean Research & Development Institute)
YU Ok Hwan (Marine Living Resources Research Division, Korea Ocean Research & Development Institute)
LEE Hyung-Gon (Marine Living Resources Research Division, Korea Ocean Research & Development Institute)
PARK Ja-Yang (ENC Corporation)
Publication Information
Korean Journal of Fisheries and Aquatic Sciences / v.37, no.4, 2004 , pp. 295-306 More about this Journal
Abstract
Spatial patterns in the macrobenthic community structure in the inter- and subtidal zones in front of the Iwon Dike and environmental variables were examined in August 2001, In total, 156 macrobenthic species(123 intertidal species and 90 subtidal species) were recorded during this study, predominately polychaetes $(40{\%})$, bivalves $(22{\%})$, and crustaceans $(22{\%})$. Polychaetes made up less than $40{\%}$ of the intertidal communitr, but more than $50{\%}$ of the subtidal community. The mean density during this study was $1,456ind./m^{2}.$ Multivariate analysis (multidimensional scaling) revealed significant differences in community structure among four regions: near the Iwon dike (B1), the high and middle intertidal zone (B2), low intertidal zone (Al), and subtidal zone (A2). The number of species, total density, and diversity (H') varied significantly among the four regions. The distribution of macrobenthic community was affected by environmental variables, such as ${\%}$ silt/clay content, total sulfide, lose of ignition, and chemical oxygen demand. These environmental variables were negatively correlated with the dominant species (Nephtys polybranchia, Umbonium thomasi, and Scoloplos armiger) in the intertidal area, but positively correlated with the dominant species (Lumbrineris cruzensis, Notomastus latericeus, and Moerella sp.) in the subtidal area. Environmental variables $({\%}\;silt/clay content and total sulfide)$ were positively correlated with the dominant species (Heteromastus filiformis) in region Bl, but negatively correlated with the dominant species (Umbonium thomasi and Scoloplos koreanus) in region B2. Amphipods Urothoe spp. and Monoculodes koreanus were the dominant species in region Al. Umbonium thomasi, the dominant species in region B2, was not found in regions Bl or Al. We suggest that the inter-specific competition for territory and exposure to seawater may be important factors controlling the macrobenthic community structure in the inter- and subtidal zones in front of the Iwon Dike.
Keywords
Macrobcnthic community; Intertidal; Subtidal; Environmental variables;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 KORDI (Korea Ocean Research and Development In- stitute). 2002. Restoration of the eastern marginal envrionment of the Yellow Sea: Creation and restora- ton of environmentally sustainable tidalflat (REYES: CREST) (1st Phase 2nd year report), pp. 505. (in Korean)
2 Lee, J.H. 1976. A study on the benthic fauna along the Busan coast, Korea. Publ. Inst. Natl. Fis. Univ., Pusan, 9, 49-70. (in Korean)
3 Lee, J.H., J.S. Hong and S.K. Yi. 1983. Studies on the benthic fauna in Garolim Bay, Korea. J. Oceanol. Soc. Korea, 18, 111-116
4 Lee, S.W., H.G. Lee and S.H. Shin. 1998. Marine biota of the macro-tidal flat of Namsari, Taebudo in the west coast of Korea. Ocean Res., 20, 105-119. (in Korean)   DOI   ScienceOn
5 Lim, H.S. and J.G. Je. 1998. Macrobenthic communities of the macro-tidal flats of Taebudo and Tando in the west coast of Korea. Ocean Res., 20, 121-130. (in Korean)   DOI   ScienceOn
6 Lim, H.S. and J.S. Hong. 2002. Spatial distribution of macrozoobenthos algong the salinity gradient and sedimentrary environment in the Watancheon estuary, Beobseongpo, southwest coast of Korea. The Sea (J. Kor. Soc. Oceanogr.), 7, 8-19. (in Korean)
7 Clarke, K.R. and M. Ainsworth. 1993. A method of linking multivariate community structure to environmental variables. Mar. Ecol. Prog. Ser., 92, 205-219   DOI
8 Clarke, K.R. and R.M. Warwick. 1994. Changes in marine communities: an approach to statistical analyses and interpretation. Nat. Environ. Res. Council, U.K., pp. 144
9 Folk, R.L. and W.C. Ward. 1957. Brazos river bar: A study in the significance of grain-size parameters. J. Sed. Pet., 267, 3-27
10 Frey, R.W., J.S. Hong, J.D. Howard, B.K. Park and S.J. Han. 1987. Zonation of benthos on macrotidal flat Inchon, Korea. Senckenbergiana Marit., 19, 295-329
11 Gordon, M.S. 1960. The effect of the deposit feeding polychaete Pectinaria gouldii on the intertidal sedi- ments Barnstable Harbor. Limnol. Oceanogr., 11, 327-332
12 Holland, A.F. and T.T. Polgar. 1976. Seasonal changes in the structure of an intertidal community. Mar. Biol., 37, 341-348   DOI
13 Hong, J.S. 1992. An environmental assessment of the coastal area using the benthic macrofauna in Kyonggi Bay, west sea, Korea: A preliminary result. Bull. Natl. Fish. Res. Dev. Agency, 46, 239-253. (in Korean)
14 Hong, J.S. and I.S. Seo. 2001. The community ecology of benthic macrofauna on the Cheokjeon tidal flat, Incheon, Korea 1. Community structure. The Sea (J. Kor. Soc. Oceanogr.), 6, 190-200. (in Korean)
15 Hong, J.S. and S.P. Yoon. 2000. Zonation of the exposed sandy beach macrofauna in Okjukpo, Taechongdo, Korea. The Sea (J. Kor. Soc. Oceanogr.), 5, 146-156. (in Korean)
16 Je, J.G., J.H. Lee and C.H. Koh. 1998. Tidal flat studies: present and future. Ocean Res., 20, 57-61. (in Korean)
17 Choi, J.W. and C.H. Koh. 1984. A study on the polychaete community in Kwangyang Bay, southern coast of Korea. J. Oceanol. Soc. Korea, 19, 153-162. (in Korean)
18 An, S. and C.H. Koh. 1992. Environments and distribution of benthic animals on the Mangyung-Dongjin tidal flat, west coast of Korea. J. Ocenol. Soc. Korea, 27, 78-90. (in Korean)
19 Beukema, J.J. 1989. Long-term changes in macrobenthic abundance on the tidal flats of the western part of the Dutch Wadden Sea. Helgolander Meeresunters., 43, 405-415   DOI
20 Brown, A.C. and A. McLachlan. 1990. Ecology of Sandy Shores, Elsevier, Amsterdam, pp. 328
21 Choi, J.W. and C.H. Koh. 1994. Macrobenthos community in Keum-Mankyung-Dongjin estuaries and its ad- jacent coastal region, Korea. J. Kor. Soc. Oceanogr., 29, 304-318. (in Korean)
22 Choi, J.W., D.S. Kim, S.H. Shin and J.G. Je. 1998. Spatial distribution of macrobenthos in the sandflat of Tae- budo, Kyonggi Bay, the west coast of Korea. Ocean Res., 20, 97-104. (in Korean)
23 Clarke, K.R. 1993. Non-parametric multivariate analyses of changes in community structure. Aust. J. Ecol., 18, 117-143   DOI
24 MOMAF (Ministry of Marine Affairs and Fisheries). 1998. Tidal flat of Korea, pp. 28. (in Korean)
25 Tamaki, A. and T. Kikuchi. 1983. Spatial arrangement of macrobenthic assemblages on an intertial sand flat, Tomioka Bay, west Kyushu. Publ. Amakusa Mar. Biol. Lab., 7, 41-60
26 Yi, S.K., J.S. Hong and J.H. Lee. 1982. A study on the subtidal benthic community in Ulsan Bay, Korea. Bull. Kor. Ocean Res. Dev. Inst., 4, 17-26. (in Korean)
27 Lim, H.S. and J.W. Choi. 1998. Macrobenthic community at the subtidal area around Taebudo in Kyeonggi Bay, Korea. J. Kor. Fish. Soc., 31, 453-462. (in Korean)
28 Lim, H.S., J.H. Lee, J.W. Choi and J.G. Je. 1995. Macro- benthic community on the soft-bottom around the Youngjong Island, Korea. J. Kor. Fish. Soc., 28, 635- 648. (in Korean)
29 Mayes, E. and D.I.D. Howie. 1985. Biochemical composi- tion and sediment temperature in relation to the reproductive cycle in the lugworm Arenicola marina. Neth. J. Sea Res., 19, 111-118   DOI   ScienceOn
30 Myer, A.C. 1977. Sediment processing in a marine subtidal sandy bottom community. 1. Physical aspects. J. Mar. Res., 35, 609-632
31 Shin, H.C. and C.H. Koh. 1990. Temporal and spatial variation of polychaete community in Kwangyang Bay, southern coast of Korea. J. Oceanol. Soc. Korea, 25, 205-216. (in Korean)
32 Park, H.S., J.H. Lee, C.S. Kim and B.M. Choi. 1998. Relationship between the spatial distribution of macro- benthic fauna and density of Umbonium thomasi on a tidal sandflat, Taebudo, Korea. Ocean Res., 20, 89-96. (in Korean)
33 Sanders, H.L., E.L. Goudsmit and G.E. Hampson. 1962. A study of the intertidal fauna of Barnstable Harbor, Massachusetts. Limnol. Oceanogr., 17, 63-79
34 Shannon, C.E. and W. Weaver. 1963. The Mathematical Theory of Communication, Univ. Illinois Press, Urbana, pp. 177
35 Shin, H.C., J.W. Choi and C.H. Koh. 1989. Faunal assemblages of benthic macrofauna in the inter- and subtidal region of the inner Kyeonggi Bay, west coast of Korea. J. Oceanol. Soc. Korea, 24, 194-193. (in Korean)
36 Koh, C.H. 1997. Korean megatidal environments and tidal power projects: Korean tidal flats - biology, ecology and land uses by reclamations and other feasibilities. La Houille Blanche., 3, 66-78
37 Koh, C.H. and H.C. Shin. 1988. Environmental charac- teristics and distribution of macrobenthos in a mudflat of the west coast of Korea (Yellow Sea). Neth. J. Sea Res., 22, 279-290   DOI   ScienceOn
38 Koo, B.J. and J.G. Je. 2002. A preliminary study on changes in macrobenthic assemblages in the fenced experi- mental plots for restoring tidal marsh, Hogok-ri tidal flat, west coast of Korea. Ocean Polar Res., 24, 63-71   DOI   ScienceOn