THERMAL IMPACTS OF A COAL POWER PLANT ON THE PLANKTON IN AN OPEN COASTAL WATER ENVIRONMENT

被引:0
作者
Choi, Keun-Hyung [1 ]
Kim, Young-Ok [2 ]
Lee, Joon-Baek [3 ]
Wang, Soon-Young [4 ]
Lee, Man-Woo [1 ]
Lee, Pyung-Gang [5 ]
Ahn, Dong-Sik [1 ]
Hong, Jae-Sang [6 ]
Soh, Ho-Young [7 ]
机构
[1] Korea Inst Coastal Ecol Inc, Bucheon Si 421742, Gyeonggi Do, South Korea
[2] Korea Ocean Res & Dev Inst, S Sea Inst, So Coastal Environm Res Dept, Geoje Si 656830, Gyungnam Do, South Korea
[3] Jeju Natl Univ, Dept Earth & Marine Sci, Jeju Si 690756, Jeju Special Se, South Korea
[4] ARA Consulting & Technol, Bucheon Si, Gyeonggi Do, South Korea
[5] Inst Ecol & Environm Inc, Incheon Si 751161, South Korea
[6] Inha Univ, Dept Ocean Sci, Inchon 402751, South Korea
[7] Chonnam Natl Univ, Div Marine Technol, Yeosu 550749, Jellanam Do, South Korea
来源
JOURNAL OF MARINE SCIENCE AND TECHNOLOGY-TAIWAN | 2012年 / 20卷 / 02期
关键词
thermal effluents; copepod; mortality; coastal waters; ACARTIA-TONSA; EGG-PRODUCTION; ZOOPLANKTON; COPEPODS; STATION; BAY; ENTRAINMENT; PASSAGE;
D O I
暂无
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
Over a five-year period, this study examined the overall impact of coal power plant cooling processes on entrained copepods and the local plankton community on the west coast of Korea. Mortality differences between the intake and discharge water of the single most dominant copepod, Acartia hongi, were positively correlated with temperature differences between the two locations. Laboratory tests showed copepod sensitivity to temperature increase, and with very low chlorine concentration applied, thermal stress was the major source of copepod mortality. Chlorophyll a concentration, ciliate abundance, and total copepod abundance at the intake showed no discernable differences from the values at the discharge. Most likely, this was due to rapid mixing of the population in the discharge water with adjacent populations in the macrotidal open coastal water environment.
引用
收藏
页码:187 / 194
页数:8
相关论文
共 38 条
[1]   The effects of power station entrainment passage on three species of marine planktonic crustacean, Acartia tonsa (Copepoda), Crangon crangon (Decapoda) and Homarus gammarus (Decapoda) [J].
Bamber, RN ;
Seaby, RMH .
MARINE ENVIRONMENTAL RESEARCH, 2004, 57 (04) :281-294
[2]  
Bollens GCR, 2003, MAR ECOL PROG SER, V257, P139
[3]   IMPACT OF POWER-PLANT DISCHARGES ON MARINE ZOOPLANKTON - A REVIEW OF THERMAL, MECHANICAL AND BIOCIDAL EFFECTS [J].
CAPUZZO, JM .
HELGOLANDER MEERESUNTERSUCHUNGEN, 1980, 33 (1-4) :422-432
[4]  
Carpenter E. J., 1969, MAR BIOL, V16, P37
[5]   SURVIVAL OF COPEPODS PASSING THROUGH A NUCLEAR-POWER STATION ON NORTHEASTERN LONG-ISLAND-SOUND, USA [J].
CARPENTER, EJ ;
PECK, BB ;
ANDERSON, SJ .
MARINE BIOLOGY, 1974, 24 (01) :49-55
[6]   Effects of thermal effluents from a power station on bacteria and heterotrophic nanoflagellates in coastal waters [J].
Choi, DH ;
Park, JS ;
Hwang, CY ;
Huh, SH ;
Cho, BC .
MARINE ECOLOGY PROGRESS SERIES, 2002, 229 :1-10
[7]  
DRESSEL D M, 1972, Chesapeake Science, V13, P156, DOI 10.2307/1351022
[8]   THE EFFECTS OF POWER-PLANT PASSAGE ON ZOOPLANKTON MORTALITIES - 8 YEARS OF STUDY AT THE DONALD-C-COOK-NUCLEAR-PLANT [J].
EVANS, MS ;
WARREN, GJ ;
PAGE, DI .
WATER RESEARCH, 1986, 20 (06) :725-734
[9]   PRESERVATION OF VITALLY STAINED ZOOPLANKTON FOR LIVE-DEAD SORTING [J].
FLEMING, JM ;
COUGHLAN, J .
ESTUARIES, 1978, 1 (02) :135-137
[10]  
FOX J L, 1975, Chesapeake Science, V16, P66, DOI 10.2307/1351086
1234