Changes of fish assemblages after construction of an estuary barrage in the lower Nakdong River, South Korea
详细信息 查看全文
- 作者:Ju-Duk Yoon ; Min-Ho Jang ; Hyun-Bin Jo ; Kwang-Seok Jeong ; Gu-Yeon Kim…
- 关键词:Estuary barrage ; Fish assemblage ; Fishway ; Freshwater fish ; Seawater fish
- 刊名:Limnology
- 出版年:2016
- 出版时间:April 2016
- 年:2016
- 卷:17
- 期:2
- 页码:183-197
- 全文大小:854 KB
- 参考文献:Amisah S, Cowx IG (2000) Response of the fish populations of the River Don in South Yorkshire to water quality and habitat improvements. Environ Pollut 108:191–199CrossRef PubMed
Anderson MJ, Gorley RN, Clarke KR (2008) PERMANOVA+ for PRIMER: guide to software and statistical methods. PRIMER-E, Plymouth
Clarke KR, Warwick WM (1994) Similarity-based testing for community pattern: the 2-way layout with no replication. Mar Biol 118:167–176CrossRef
Clay CH (1995) Design of fishways and other fish facilities. Lewis Publishers, Boca Raton
Craig JF (2000) Large dams and freshwater fish biodiversity. In: Contributing paper prepared for thematic review II. 1: Dams, ecosystem functions and environmental restoration. World Commission on Dams
Drinkwater KF, Frank KT (1994) Effects of river regulation and diversion on marine fish and invertebrates. Aquat Conserv 4:135–151CrossRef
Eklov A, Greenberg L, Bronmark C, Larsson P, Berglund O (2002) Response of stream fish to improved water quality: a comparison between the 1960s and 1990s. Freshw Biol 40:771–782CrossRef
Field JG, Clarke KR, Warwick M (1982) A practical strategy for analyzing multi-species distribution patterns. Mar Ecol Prog Ser 8:37–53CrossRef
Gray A (1992) The ecological impact of estuarine barrages. British Ecological Society/Field Studies Council, Shrewsbury
Ha K, Kim HW, Joo GJ (1998) The phytoplankton succession in the lower part of hypertrophic Nakdong River (Mulgum), South Korea. Hydrobiologia 369:217–227CrossRef
Johnson PTJ, Olde JD, Vander Zanden MJ (2008) Dam invaders: impoundments facilitate biological invasions into freshwaters. Front Ecol Environ 6:357–363CrossRef
Joy MK, Death RG (2001) Control of freshwater fish and crayfish community structure in Taranaki, New Zealand: dams, diadromy or habitat structure? Freshw Biol 46:417–429CrossRef
Kim IS, Choi Y, Lee CL, Lee YJ, Kim BJ, Kim JH (2005) Illustrated book of Korean fishes. Kyohak publishing, Seoul (in Korean)
Kruk A (2007) Role of habitat degradation in determining fish distribution and abundance along the lowland Warta River, Poland. J Appl Ichthyol 23:9–18CrossRef
Kwak SN, Huh SH (2003) Changes in species composition of fishes in the Nakdong River Estuary. Korean Soc Fish Aquat Sci 36:129–135 (in Korean)
Kwater (1985) Ecosystem investigation of the lower Nakdong River (1st year) (in Korean)
Kwater (1987) Ecosystem investigation of the lower Nakdong River (3rd year) (in Korean)
Kwater (1988) Environment monitoring at the lower Nakdong River (in Korean)
Kwater (1990) Environment monitoring at the lower Nakdong River (in Korean)
Kwater (1991) Environment monitoring at the lower Nakdong River (in Korean)
Kwater (1992) Report of environment monitoring at the lower Nakdong River (in Korean)
Kwater (1993) Report of environment monitoring at the lower Nakdong River (in Korean)
Kwater (1994) Report of environment monitoring at the lower Nakdong River (in Korean)
Kwater (1995) Report of environment monitoring at the lower Nakdong River (in Korean)
Kwater (1996) Report of environment monitoring at the lower Nakdong River (in Korean)
Kwater (2003) Study of migratory fish around the Nakdong River Estuary barrage (in Korean)
Kwater (2007) Investigation of current habitat status and migration pattern for fishes inhabit around Nakdong River Estuary (in Korean)
Leung E, Rosenfeld J, Bernhardt J (2009) Habitat effects on invertebrate drift in a small trout stream: implications for prey availability to drift-feeding fish. Hydrobiologia 623:113–125CrossRef
Lucas MC, Baras E (2001) Migration of freshwater fishes. Blackwell science, OxfordCrossRef
Magnuson JJ, Crowder LB, Medvick PA (1979) Temperature as an ecological resource. Am Zool 19:331–343CrossRef
Mitchell AL, Knouft JH (2009) Non-native fishes and native species diversity in freshwater fish assemblages across the United States. Biol Invasions 11:1441–1450CrossRef
Morisita M (1959) Measuring of interspecific association and similarity between assemblages. Memoirs Biol 3:65–80
Moyle PB, Cech JJ (2000) Fishes: an introduction to ichthyology, 4th edn. Prentice Hall Inc, New Jersey
Quinñones RA, Montes RM (2001) Relationship between freshwater input to the coastal zone and the historical landing of the benthic/demersal fish Eleginops maclovinus in central-south Chile. Fish Oceanogr 10:311–328CrossRef
Raat A (2001) Ecological rehabilitation of the Dutch part of the River Rhine with special attention to the fish. Regul River 17:131–144CrossRef
Rahel FJ (2002) Homogenization of freshwater faunas. Ann Rev Ecol Syst 33:291–315CrossRef
Robins J, Mayer D, Staunton-Smith J, Halliday I, Sawynok B, Sellin M (2006) Variable growth rates of the tropical estuarine fish barramundi Lates calcarifer (Bloch) under different freshwater flow conditions. J Fish Biol 69:379–391CrossRef
Salen-Picard C, Darnaude AM, Arlhac D, Harmelin-Vivien ML (2002) Fluctuations of macrobenthic populations: a link between climate-driven river run-off and sole fishery yields in the Gulf of Lions. Oecologia 133:380–388CrossRef
Sinha M, Mukhopadhyay M, Mitra P, Bagchi M, Karamkar H (1996) Impact of Farakka barrage on the hydrology and fishery of Hoogly estuary. Estuaries 19:710–722CrossRef
Turek JG, Goodger TE, Bigford TE, Nichols JS (1987) Influence of freshwater inflows on estuarine productivity. NOAA Technical Report NMFS-F/NEC-46
Vannote R, Minshall G, Cummins K, Sedell J, Cushing C (1980) The river continuum concept. Can J Fish Aquat Sci 37:130–137CrossRef
Winter H, Van Densen W (2001) Assessing the opportunities for upstream migration of non-salmonid fishes in the weir-regulated River Vecht. Fish Manag Ecol 8:513–532CrossRef
Yang HJ, Kim KH, Kum JD (2001) The fish fauna and migration of the fishes in the fish way of the Nakdong River Mouth Dam. Korean J Limnol 34:251–258 (in Korean) - 作者单位:Ju-Duk Yoon (1)
Min-Ho Jang (2)
Hyun-Bin Jo (3)
Kwang-Seok Jeong (4)
Gu-Yeon Kim (4)
Gea-Jae Joo (3)
1. Biological Resource Center, Kongju National University, Gongju, 314-701, South Korea
2. Department of Biology Education, Kongju National University, Gongju, 314-701, South Korea
3. Department of Integrated Biological Science, Pusan National University, Busan, 609-735, South Korea
4. Institute of Environmental Technology and Industry, Pusan National University, Busan, 609-735, South Korea - 刊物类别:Biomedical and Life Sciences
- 刊物主题:Life Sciences
Ecology
Environment
Hydrobiology - 出版者:Springer Japan
- ISSN:1439-863X
文摘
In the Nakdong River, an estuary barrage was constructed in 1987, and it divided the freshwater and the seawater, resulting in a change in the ecosystem. To estimate the impact of barrage construction on fish assemblages, we evaluated 20 years of monitoring data before and after the construction of the estuary barrage, and evaluated the role of fishways. The barrage construction generated entire changes of fish assemblages. After construction, the number of fish species dropped sharply, and 36 species disappeared. Conversely, 18 species appeared at this site, including eight freshwater species, seven of which were exotic or translocated species. Barrage construction affected freshwater fish more severely than it did estuarine and marine species because of the existence of an estuarine environment below the barrage. We did not detect any evidence of recovery of fish assemblages. A total of 31 species were collected at fishways, and the number of individuals collected at each fishway was positively correlated with the amount of discharge from the estuary barrage, mean daily tide level, and water temperature. Migratory fish using a fishway had obvious occurrence periods. Therefore, the efficiency of fishway use can be increased if an appropriate management plan is prepared and implemented.