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http://dx.doi.org/10.5657/KFAS.2019.0511

Site Assessment Using Habitat Suitability Index for Manila Clam Ruditapes philippinarum in Geunso Bay Tidal Flats  

Choi, Yong-Hyeon (Tidal Flat Research Center, National Institute of Fisheries science)
Hong, SokJin (Tidal Flat Research Center, National Institute of Fisheries science)
Jeon, Seung-Ryul (Tidal Flat Research Center, National Institute of Fisheries science)
Cho, Yoon-Sik (Marine and Fisheries Environment Impact Assessment Center, National Institute of Fisheries science)
Publication Information
Korean Journal of Fisheries and Aquatic Sciences / v.52, no.5, 2019 , pp. 511-518 More about this Journal
Abstract
Evaluating the habitat suitability of potential aquaculture sites for cultured species is critical to the sustainable use of tidal flats. This study evaluated the habitat suitability index (HSI) of 12 sites in a tidal flat aquaculture farm at Geunso Bay, Taean, in June 2016. The parameters used to model the suitability index were Growth (water temperature, chlorophyll ${\alpha}$, hydrodynamics), Survival (sediment-sand, mean size, air exposure), and Environment (DO, salinity). The HSI was calculated using weighted and No weighted geometric means. The results showed high habitat suitability at the bay's entrance (HIS; No weighted, 0.60-0.70; weighted, 0.60). Hydrodynamics, air exposure, sediment-sand and mean size are thought to have a significant impact on habitat selection by Manila clams Ruditapes philippinarum. This study explored the optimum habitat for Manila clams by calculating the HSI, providing basic data for tidal flat management.
Keywords
Habitat suitability index; Tidal flat aquaculture; Ruditapes philippinarum; Suitable site assessment; Geunso Bay;
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Times Cited By KSCI : 5  (Citation Analysis)
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1 Ali F and Nakamura K. 2000. Metabolic characteristics of the Japanese clam Ruditapes philippinarum (Adams & Reeve) during aerial exposure. Aquac Res 31, 157-165.   DOI
2 Ali F and Nakamura K. 1999. Effect of temperature and relative humidity on the tolerance of the Japanese clam, Ruditapes philippinarum (Adams & Reeve), to air exposure. Aquacult Res 30, 629-636.   DOI
3 Baek SH, Lee JY, Lee HO and Han MS. 2008. Study of the Food Characteristics on Pacific Oyster Crassostrea gigas and Manila Clam Ruditapes phillippinarum in the Intertidal Zone of Taeahn, Korea. Korean J Environ Biol 26, 145-152.
4 Cha JH, An SJ, Koo MH, Kim HC, Song YH and Suh MS. 2008. Effects of Porosity and Water Content on Thermal Conductivity of Soils. J Soil Groundwater Environ 13, 27-36.
5 Cho YS, Lee WC, Hong SJ, Kim HC and Kim JB. 2012. GISbased suitable site selection using habitat suitability index for oyster farms in Geoje-Hansan Bay, Korea. Ocean Coastal Management 56, 10-16.   DOI
6 Choi YH, Choi YS, Cho YS, Kim YT and Jeon SR. 2016. A Study on the Habitait Suitability Considering Survival, Growth, Environment for Ruditapes philippinarum in Geunso Bay (Pado and Beopsan). J Kor Soc Mar Environ Saf 22, 724-731. https://doi.org/10.7837/kosomes.2016.22.6.723.
7 Choi JK, No JH, Ryu JH, Eom JA and No SM. 2010. Analysis on the Sedimentary Environment and Microphytobenthos Distribution in the Geunso Bay Tidal Flat Using Remotely Sensed Data. J Wetl Res 12, 67-78.
8 Choi JK, Ryu JH, Woo HJ and Eom JA. 2011. A Study on the Flushing Characteristics in Geunso Bay using Hydro-hypsographic Analysis. J Kor Wetl Soc 13, 45-52. https://doi.org/10.17663/JWR.2011.13.1.045.
9 Chung EY, Shin YK and Hur SB. 1999. Physiological rhythms in the Oxygen Consumption and Filtration Rates of the Manila Clam, Ruditapes philippinarum. Korean J Malacol 15, 127-131.
10 Eom JA, Choi JK, Ryu JH, Woo HJ, Won JS and Jang S. 2012. Tidal channel distribution in relation to surface sedimentary facies based on remotely sensed data. Geosciences J 16, 127-137. https://doi.org/10.1007/s12303-012-0015-6.   DOI
11 Gibson LA, Wilson BA, Cahill DM and Hill J. 2004. Modelling habitat suitability of the swamp antechinus(Antechinus minimus maritimus) in the coastal heathlands of southern Victoria. Austr Biol Conserv 117, 143-150. https://doi.org/10.1016/S0006-3207(03)00288-X.   DOI
12 Grizzle RE, Langan R and Howell WH. 1992. Growth responses of suspension-feeding bivalve molluscs to changes in water flow: differences between siphonate and nonsiphonate taxa. J Exp Biol Ecol 162, 213-228.   DOI
13 Hamilton EL and Bachman RT. 1982. Sound velocity and related properties of marine sediments. J Acoust Soc Am 72, 1891-1904.   DOI
14 Han HS, Ma CW and Kim JY. 2012. Growth Patterns of the Manila Clam, Ruditapes philippinarum at Each Tidal Level in the Intertidal Zone in Tae-an, West Coast of South Korea. Korean J Malacol 28, 29-35. https://doi.org/10.9710/kjm.2012.28.1.029.   DOI
15 Folk RL. 1954. The distinction between grain size and mineral composition in sedimentary rock nomenclature. J Geol 62, 344-359.   DOI
16 Jeon SR, Choi YS, Cho YS, Kim YT and Choi YH. 2015. Suitable Site Assessment using Habitat Suitability Index for Ruditapes philippinarum in Gochang(Hajun). J Kor Soc Mar Environ Saf 21, 484-491. https://doi.org/10.7837/kosomes.2015.21.5.484.   DOI
17 KHOA (Korea Hydrographic and Oceanographic Agency). 2015. Korea ocean observing and forecasting system. Retrieved from http://www.khoa.go.kr/tdnet/ on Aug 08, 2018.
18 Kim DS and Kim KH. 2008. Tidal and seasonal variations of nutrients in Keunso Bay, the Yellow Sea. Ocean Polar Res 30, 1-10. https://doi.org/10.4217/OPR.2008.30.1.001.
19 Kim WS, Hur HT, Hur SH and Lee TW. 2001. Effects of salinity on endogenous rhythm of the Manila clam Ruditapes philippinarum (Bivalvia: Veneridae). Mar Bio 138, 157-162. https://doi.org/10.1007/s002270000430.   DOI
20 Kurasige H. 1942. Air temperature and vital force in exposure of Venerupis philippinarum. Venus 11, 134-142.
21 Lee SR, Choi JK, Park IH, Koo BJ, Ryu JH and Lee YK. 2014. Application of geospatial models to map potential Ruditapes philippinarum habitat using remote sensing and GIS. Int J Remote Sens 35, 3875-3891. https://doi.org/10.1080/01431161.2014.919680.   DOI
22 Laing I and Child AR. 1996. Comparative tolerance of small juvenile palourdes (Tapes decussates L.) and Manila clams (Tapes philippinarum Adams & Reeve) to low temperature. J Exp Mar Biol Ecol 195, 267-285. https://doi.org/10.1016/0022-0981(95)00097-6.   DOI
23 Longdill P, Healy TR and Black KP. 2008. An integrated GIS approach for sustainable aquaculture management area site selection. Ocean Costal manage 51, 612-624. https://doi.org/10.1016/j.ocecoaman.2008.06.010.   DOI
24 MOF (Ministry of Oceans and Fisheries). 2018. Sea and ecology information System. Retrieved from https://www.ecosea.go.kr/ on Aug 26, 2019.
25 MLTMA (Ministry of Land, Transport and Maritime Affairs). 2012. National Survey of Coastal Wetlands. MLTMA, Sejong, Korea, 185.
26 Min KS, Lee SJ, Kim BH and Park KY. 2004. Tolerance against Water Temperature and Growth of Ruditapes philippinarum Spats in Differnet Substrates. Korean J Malacol 20, 121-124.
27 MOF (Ministry of Oceans and Fisheries). 2013. Marine environment standard methods. MOF, Daejeon, Korea, 495.
28 Mulholland R. 1984. Habitat suitability index models: Hard clam, Biological Report FWS/OBS-82/10.77, U.S. Fish and Wildlife Service, U.S. Dept. Int, Washington DC, U.S.A., 12.
29 KMA (Korea Meteorological Administration). 2019. Korea climate data Portal. Retrieved from https://www.data.kma.go.kr/ on Aug 08, 2018.
30 NIFS (National Fisheries Research and Development Institue). 2019. Annual report of marine environment monitoring around aquaculture area in Korea. NIFS, Busan, Korea, 164.
31 NFRDI (National Fisheries Research and Development Institute). 2014a. 100 Items of fishery products (Shellfish). NFRDI, Busan, Korea, 118-136.
32 NFRDI (National Fisheries Research and Development Institute). 2014b. 1/2 Technical report of national fisheries research & development institute. NFRDI, Busan, Korea, 145-164.
33 Numaguchi K. 1998. Preliminary experiments on the influence of water temperature, salinity and air exposure on the mortality of Manila clam larvae. Aquac Int 6, 77-81. https://doi.org/10.1023/A:1009225921044.   DOI
34 Tezuka N, Kanematsu M, Asami K, Sakiyama K, Hamaguchi M and Usuki H. 2013. Effect of Salinity and Substrate Grain Size on Larval Settlement of the Asari clam(Manila clam, Ruditapes philippinarum). J exp Mar Biol Ecol 439, 108-112. https://doi.org/10.1016/j.jembe.2012.10.020.   DOI
35 Paillard C, Allam B, and Oubella R. 2004. Effect of temperature on defense parameters in Manila clam Ruditapes philippinarum challenged with Vibrio tapetis. Diseases of Aquatic Organisms 59, 249-262. https://doi.org/10.3354/dao059249.   DOI
36 Shin YK, Kim Y, Chung EY and Hur SB. 2001. Effects of the Dissolved Oxygen Concentration on the Physioligy of the Manila clam, Ruditapes philippinarum. J Korean Soc Fish Res 34, 190-193. https://doi.org/10.5657/kfas.2002.35.5.485.
37 Shin YK, Kim Y, Chung EY and Hur SB,.2000. Temperature and Salinity Tolerance of the Manila Clam, Ruditapes philippinarum. J Korean Soc Fish Res 33, 213-218.
38 USFWS (U.S. Fish and Wildlife Service). 1980. Habitat as a basis for environmental assessment, Ecological Services Manual 101. Division of Ecological Services, U.S. Dept. Int., Washington DC, U.S.A., 29.
39 Vincenzi S, Caramori G, Rossi R and Leo GAD. 2006. A GISbased habitat suitability model for commercial yield estimation of Tapes philippinarum in a Mediterranean coastal lagoon (Sacca di Goro, Italy). Ecol Model 193, 90-104. https://doi.org/10.1016/j.ecolmodel.2005.07.039.   DOI
40 Yoo JW, Hwang IS and Hong JS. 2007. Inference Models for Tidal Flat Elevation and Sediment Grain Size: A Preliminary Approach on Tidal Flat Macrobenthic Community. Ocean Sci J 42, 69-79. https://doi.org/10.1007/BF03020875.   DOI