Browse > Article
http://dx.doi.org/10.4217/OPR.2020.42.3.233

The Influence of the Dissolved Oxygen of Bottom Water on the Temporal Variation of the Benthic Polychaetous Community Structure in Dangdong Bay  

Yang, Jin Kyeong (Department of Ocean Integrated Science, College of Fisheries and Ocean Sciences, Chonnam Natinal University)
Shin, Hyun Chool (Department of Ocean Integrated Science, College of Fisheries and Ocean Sciences, Chonnam Natinal University)
Publication Information
Ocean and Polar Research / v.42, no.3, 2020 , pp. 233-247 More about this Journal
Abstract
This study was carried out at 5 sites 11 times over two years to identify the variation of benthic environments and benthic polychaetous community and analyze the benthic healthiness in Dangdong Bay, a small semi-enclosed inner bay of Jinhae Bay. The temperature of bottom water showed the typical temporal fluctuation of a temperate zone and was in the range of 5.94 ~ 23.94℃. The salinity did not change significantly during the study period and was in the range of 32.93 ~ 35.72 psu. The concentration of dissolved oxygen of bottom water fluctuated a great deal and was in the range of 0.31 ~ 10.20 mg/L. The lowest DO value was recorded in July 2015, as 0.31±0.04 mg/L corresponding to the hypoxic water mass. The hypoxic water mass was formed continuously at some sites also in July and August 2016. The mean grain size was in the range of 7.57 ~ 9.81Ø and the average was 8.89±0.20Ø. The surface sediments were mainly composed of fine sediment (mud) above 85%. The mean of TOC was 3.09±0.22% and LOI was 13.30±0.47%, showing very high levels in Korean coastal waters. The concentration of AVS was in the range of 0.33 ~ 1.28 mgS/g-dry. The high values of organic contents and AVS indicated that there had been the serious organic enrichment in Dangdong Bay. The number of species and the density of the benthic polychaetous community in Dangdong Bay were in the range of 2 ~ 38 species and 2 ~ 2,185 ind./㎡ during the study period. The number of species and density were highly sustained in winter and spring, and then decreased gradually with the formation of a hypoxic water mass in summer, and the lowest number of species and density were recorded in autumn. In September and November 2015, the dead zone expanded to almost the whole study area. Dominant polychaetous species were Capitella capitata, Lumbrineris longifolia, Paraprionospio patiens and Sigambra tentaculata, each known as opportunistic species and potential organic pollutant indicator species. In particular, Paraprionospio patiens showed a very high population density of 2,019 ind./㎡ in December 2016. Polychaetous communities at each sampling time were classified into 4 temporal groups according to dominant species in each period by cluster analysis and nMDS. 'Period Group AI' was formed in winter and spring of 2015, dominated by Capitella capitata, 'Period AII' in summer dominated by Lumbrineris longifolia, 'Period B' in autumn with no fauna in the dead zone, and particularly 'Period C' in winter of 2016 dominated by Paraprionospio patiens. As a result of analysis of benthic healthiness, the study area was estimated to be in a Fair~Very Poor condition by AMBI and in a Poor~Very Poor condition by BPI during the study period. Both AMBI and BPI showed that the study area was in a Very Poor condition in September and November 2015, and when the dead zone occurred. In Dongdong Bay, the fact that the formation of a hypoxic water mass occurred in summer and a dead zone in autumn were confirmed. In addition, the dominance of opportunistic and organic pollutant indicator species was also observed clearly. The benthic healthiness indexes such as AMBI and BPI showed that organic enrichment was serious in Dangdong Bay.
Keywords
dissolved oxygen; benthic polychaetous community; benthic healthness index; temporal variation; Dangdong bay;
Citations & Related Records
Times Cited By KSCI : 7  (Citation Analysis)
연도 인용수 순위
1 Neofitou N, Vafidis D, Klaoudato S (2010) Spatial and temporal effects of fish farming on benthic community structure in a semi-enclosed gulf of the Eastern Mediterranean. Aquacult Environ Interact 1:95-105   DOI
2 Paik SG, Yun SG (2000) Community structure of the macrobenthos in Chinhae Bay, Korea. J Korean Fish Soc 33(6):572-580
3 Park SY (2016) Organic matter and nutrient dynamics with the development of hypoxia in Jinhae Bay, Korea. MS Thesis, Pusan National University, 97 p
4 Pearson TH, Rosenberg R (1978) Macrobenthic succession in relation to organic enrichment and pollution of the marine environment. Oceanogr Mar Biol 16:229-311
5 Pielou EC (1966) The measurement of diversity in different types of biological collections. J Theoret Biol 13:131-144   DOI
6 Pocklington P, Wells PG (1992) Polychaetes: Key taxa for marine environmental quality monitoring. Mar Pollut Bull 24:593-598   DOI
7 Rygg B (1985) Distribution of species along pollution-induced diversity gradients in benthic communities in Norwegian Fjords. Mar Pollut Bull 16:469-474   DOI
8 Seo JY (2016) A Study on the determination of threshold value of benthic community health and application of Benthic Pollution Index (BPI) to special management areas the southern coasts of Korea. Ph.D. Thesis. Pusan National University, 138 p
9 Seo JY, Lim HS, Choi JW (2015) Spatio-temporal distribution of macrobenthic communities in Jinhae Bay, Korea. Ocean Polar Res 37(4):295-315   DOI
10 Seo JY, Park SH, Lee JH, Choi JW (2012) Structural changes in macrozoobenthic communities due to summer hypoxia in Gamak Bay. Ocean Sci J 47(1):27-40   DOI
11 Shannon CE, Weaver W (1963) The mathematical theory of communication. University of Illinois Press, Urbana, 125 p
12 Shin HC (1995) Benthic polychaetous community in Kamak Bay, southern coast of Korea. J Korean Soc Oceanogr 30(4):250-261
13 Shin HC, Choi JW, Koh CH (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(4):184-193
14 Shin HC, Choi SS, Koh CH (1992) Seasonal and spatial variation of polychaetous community in Youngil Bay, spitheastern Korea. J Oceanol Soc Kor 27(1):46-54
15 Shin HC, Koh C (1990) Temporal and spatial variation of polychaete community in Kwangyang Bay, southern coast of Korea. J Oceanol Soc Kor 25(4):205-216
16 Sutherland TF, Levings CD, Petersen SA, Poon P, Piercey B (2007) The use of meiofauna as an indicator of benthic organic enrichment associated with salmonid aquaculture. Mar Pollut Bull 54:1249-1261   DOI
17 Tomassetti P, Porrello S (2005) Polychaetes and indicator of marine fish farm organic enrichment. Aquacult Intern 13:109-128   DOI
18 Tsutsumi H (1990) Population persistence of Capitella sp. (Polychaeta; Capitellidae) on mud flat subject to environmental disturbance by organic enrichment. Mar Ecol-Prog Ser 63:147-156   DOI
19 Warwick RM (1993) Environmental impact studies on marine communities: Pragmatical considerations. Austral J Ecol 18:63-80   DOI
20 Weston D (1990) Quantitative examination of macrobenthic community changes along an organic enrichment gradient. Mar Ecol-Prog Ser 61:233-244   DOI
21 Folk RL, Ward WC (1957) Razos river bar: A study in the significance of grain size parameters. J Sedment Petol 27:3-26   DOI
22 Gamito S (2008) Three main stressors acting on the Ria Formosa lagoonal system (Southern Portugal): Physical stress, organic matter pollution and the land-ocean gradient. Estuar Coast Shelf S 77:710-720   DOI
23 Woo JS, Choi HS, Lee HJ, Kim TH (2014) Organic matter in the sediments of Youngsan river estuary : Distribution and sources. J Env Sci Int 23(7):1375-1383   DOI
24 Yi SK, Hong JH, Lee JH (1982) A study on the subtidal benthic community in Ulsan Bay, Korea. Bull KORDI 4:17-26
25 Yokoyama H (2000) Environmental quality criteria for aquaculture farms in Japanese coastal area - A new policy and its potential problems. Bull Nat Res Inst Aquacult 29:123-134
26 Yokoyama H, Choi JW (2010) New records of three Paraprionospio species (Polychaeta: Spionodae) from Korean waters. Ocean Sci J 45(1):55-61   DOI
27 Yoon SP, Kim YJ, Jung RH, Moon CH, Hong SJ, Lee WC, Park JS (2008) Benthic environments and macrobenthic polychaete community structure in the winter of 2005-2006 in Gamak Bay, Korea. The Sea 13(1):67-82
28 Fauchald K, Jumars PA (1979) The diet of worms: A study of polychaete feeding guilds. Oceanogr Mar Biol 17:193-284
29 Ingram RL (1971) Sieve analysis. In: Carver RE (ed) Procedures in sedimentary petrology. Willy-Interscience, Calofornia, pp 49-67
30 Hong JS, Jung RH, Sea IS, Yoon KT, Choi BM, Yoo JW (1997) How are the spatio-temporal distribution patterns of benthic macrofaunal communities affected by the construction of Shihwa Dike in the west coast of Korea? J Korean Fish Soc 30(5):882-895
31 Jang SY, Shin HC (2016) Differences in the community structures of macrobenthic polychaetes from farming grounds and natural habitats in Gamak Bay. J Korean Soc Mar Environ Energy 19(4):297-309   DOI
32 Jung, RH, Lim HS, Kim SS, Park JS, Jeon, KA, Lee YS, Lee, JS, Kim KY, Go WJ (2002) A study of the macrozoobenthos at the intensive fish famming grounds in the southern coast of Korea. The Sea 7(4):235-246
33 Jung RH, Sea IS, Choi MK, Park SR, Choi BM, Kim MH, Kim YJ, Yun JS (2014a) Community structure and health assessment of macrobenthic assemblages during spring and summer in the shellfish farming ground of Wonmun Bay, on the southern coast of Korea. Korean J Fish Aquat Sci 47(6):908-926   DOI
34 Jung RH, Sea IS, Lee WC, Kim HC, Park SR, Kim JB, Oh CW, Choi BM (2014b) Community structure and health assessment of macrobenthic assemblages at spring and summer in Cheonsu Bay, wet coast of Korea. The Sea 19(4):272-286   DOI
35 Kwon KY, Lee YH, Shim JM, Lee PY (2010) Occurrence and variation of oxygen deficient water mass in the Namdae stream estuary, Yangyang, Korea. The Sea 15(3):115-123
36 Kim JG, Jang HS (2014) Evaluation of characteristics of particle composition and pollution of heavy metals for bottom sediments in Cheonsu Bay, Korea - Comparison of the sediments environment of farming area and non-farming area. J Korean Soc Mar Env Safe 20(4):358-371   DOI
37 Kim KT, Kim ES, Cho SR, Park JK, Kim JK, Lee JM (2008) Distribution of TOC and metal in the surface sediments of the Lake Shihwa. In: The Korean Society of Marine Environment and Safety, Spring Annual Confernce 2018, Mokpo National Maritime University, 13 May 2008, pp 159-164
38 Kim YJ (2017) Fluctuation of benthic environment and benthic polychaete community in hypoxia waters of Jinhae Bay. MS Thesis, Junnam National University, 135 p
39 Lee IC, Gong HH, Yoon SJ (2008) Numerical prediction for reduction of oxygen deficient water mass by ecological model in Jinhae Bay. J Ocean Eng Tech 22(5):75-82
40 Lim HS (1993) Ecology on the macrozoobenthos in Chinhae Bay of Korea. Ph.D. Thesis, Pusan National University, 311 p
41 Lim HS, Diaz RJ, Hong JS, Schaffner LC (2006) Hypoxia and benthic community recovery in Korean coastal waters. Mar Pollut Bull 52:1517-1526   DOI
42 Lim HS, Choi JW, Je JG, Lee JH (1992) Distribution pattern of macrozoobenthos at the farming ground in the western part of Chinhae Bay, Korea. Bull Korean Fish Soc 25(2):115-132
43 Lim HS, Hong JS (1994a) An environmental impact assessment based on the benthic macrofauna in Chinhae Bay, Korea - An application of some graphic methods by distribution pattern of individuals among species. Bull Korean Fish Soc 27(5):659-672
44 Belan TA (2004) Marine environmental quality assessment using polychaete taxocene characteristics in Vancouver Harbour. Mar Environ Res 57:89-101   DOI
45 Anderson M (2008) Animal-sediment relationships re-visited: Characterising species distributions along an environmental gradient using canonical analysis and quantile regression splines. J Exp Mar Biol Ecol 366:16-27   DOI
46 Bae HN (2015) Spatial and seasonal variations of macrozoobenthic communities of south-west part of Jinhae Bay, Korea. MS Thesis. Seoul National University, 65 p
47 Bannister RJ, Valdemarsen T, Hansen PK, Holmer M, Ervik A (2014) Changes in benthic sediment conditions under an Atlantic salmon farm at a deep, well-flushed coastal site. Aquacult Environ Interact 5:29-47   DOI
48 Bilyard GR (1987) The value of benthic infauna in marine pollution monitoring studies. Mar Pollut Bull 18:581-585   DOI
49 Lim HS, Hong JS (1997a) Ecology of the macrobenthic community in Chinhae Bay, Korea 2. Distribution pattern of the major dominant species. J Korean Fish Soc 30(2):161-174
50 Lim HS, Hong JS (1994b) Ecology of the macrobenthic community in Chinhae Bay, Korea 1. Benthic environment. Bull Korean Fish Soc 27(2):200-214
51 Lim HS, Hong JS (1997b) Ecology of the macrobenthic community in Chinhae Bay, Korea 3. Community structure. J Korean Fish Soc 30(2):175-187
52 Lim KH, Shin HC (2005) Temporal and spatial distribution of benthic polychaetous community in the northern Jinhae Bay. Korean J Environ Biol 23(3):238-249
53 Lim KH, Shin HC, Yoon SM, Koh CH (2007) Assessment of benthic environment based on macrobenthic community analysys in Jinhae Bay, Korea. The Sea 12(1):9-23
54 Lorenzen CJ (1967) Determination of chlorophyll and pheopigments: Spectrophotometric equations. Limnol Oceanogr 12:343-346   DOI
55 Margalef R (1958) Information theory in ecology. Gen Syst 3:157-175
56 Martinez-Garcia E, Sanchez-Jerez P, Aguado-Gimenz F, Avila P, Guerrero A, Sanchez-Liazo JL, Fermandez-Gonzalez V, Gonzalez N, Gairin JI, Carballeria C, Garcia-Garcia B, Carreras J, Macias JC, Carballeria A, Collado C (2013) A meta-analysis approach to the effects of fish farming on soft bottom polychaeta assemblages in temperate regions. Mar Pollut Bull 69:165-171   DOI
57 McNaughton SJT (1968) Structure and function in California grasslands. Ecology 49(5):962-972   DOI
58 MOF (2016) Development of hypoxic water mass restoration technology in a inner bay. Ministry of Oceans and Fisheries, Seoul, 1138 p
59 Borja A, Franco J, Valencia V, Bald J, Muxika I, Belzune MJ, Solaun O (2004) Implementation of the European water framework directive from the Basque country (northern Spain): A methodological approach. Mar Pollut Bull 48:209-218   DOI
60 Borja A, Franco J, Perez V (2000) A marine biotic index to establish the ecological quality of soft-bottom benthos within European estuarine and coastal environments. Mar Pollut Bull 40(12):1100-1114   DOI
61 Choi JW, Hyun SM, Chang M (2003) The summer benthic environmental conditions assessed be the functional groups of macrobenthic fauna in Gwangyang Bay, southern coast of Korea. Korean J Environ Biol 21(2):101-113
62 Bray JR, Curtis JT (1957) An ordination of the upland forest communities of southern Wisconsin. Ecol Monogr 27:325-349   DOI
63 Cho HY, Chae JW, Chun SY (2002) Stratification and DO concentration changes in Chinhae-Masan Bay. J Korean Soc Coast Ocean Eng 14(4):295-307
64 Cho YS, Lee WC, Kim JB, Hong SJ, Kim HC, Kim CS (2013) Establishment of environmental assessment using sediment total organic carbon and macrobenthic polychaete community in shellfish farms. J Korean Soc Mar Environ Safe 19(5):430-438   DOI
65 Choi JW, Seo JY (2007) Application of biotic indices to assess the health condition of benthic community in Masan Bay, Korea. Ocean Polar Res 29(4):339-348   DOI
66 Del-Pilar-Ruso, Y, De-La-Ossa-Carretero JA, Loya-Fermandez A, Ferrero-Vicente LM, Gimenez-Casaiduero F, Sanchez-Lizaso JL (2009) Assessment of soft bottom Polychaeta assemblage affected by a spatial confluence of impacts: Sewage and brine discharge. Mar Pollut Bull 60:1930-1938   DOI
67 Essink K (2003) Response of an estuarine ecosystem to reduced organic waste discharge. Aquat Ecol 37:65-76   DOI