Diel vertical migration of the copepod <i>Calanus sinicus</i> before and during formation of the Yellow Sea Cold Bottom Water in the Yellow Sea

KANG Jung-Hoon; SEO MinHo; KWON Oh Youn; KIM Woong-Seo

doi:10.1007/s13131-013-0357-6

Article Contents

Article Navigation > Acta Oceanologica Sinica > 2013 > 32(9): 99-106

KANG Jung-Hoon, SEO MinHo, KWON Oh Youn, KIM Woong-Seo. Diel vertical migration of the copepod Calanus sinicus before and during formation of the Yellow Sea Cold Bottom Water in the Yellow Sea[J]. Acta Oceanologica Sinica, 2013, 32(9): 99-106. doi: 10.1007/s13131-013-0357-6

Citation:

KANG Jung-Hoon, SEO MinHo, KWON Oh Youn, KIM Woong-Seo. Diel vertical migration of the copepod Calanus sinicus before and during formation of the Yellow Sea Cold Bottom Water in the Yellow Sea[J]. Acta Oceanologica Sinica, 2013, 32(9): 99-106. doi: 10.1007/s13131-013-0357-6

Citation:

PDF( 1008 KB)

Diel vertical migration of the copepod Calanus sinicus before and during formation of the Yellow Sea Cold Bottom Water in the Yellow Sea

doi: 10.1007/s13131-013-0357-6

1.
South Sea Environment Research Division, Korea Institute of Ocean Science & Technology (KIOST), 41 Jangmok1-gil, Jangmok-myon, Geoje 656-834, Republic of Korea
2.
Deep-sea and Seabed Resources Research Division, KIOST, Ansan P.O. Box 29, Seoul 425-600, Republic of Korea

Received Date: 2012-06-15
Rev Recd Date: 2012-12-24

Abstract

Abstract

To understand the effects of the Yellow Sea Cold Bottom Water (YSCBW) on the diel vertical migration (DVM) of the copepod Calanus sinicus, we surveyed vertical distribution of C. sinicus at a fixed station in the Yellow Sea before (spring) and during (summer) formation of the YSCBW. Cold water (<10℃) was observed in the bottom layer when the water column was ther mally stratified in summer, but the water column was thermally well-mixed in spring 2010. Samples were collected from five different layers at 3-h intervals using an opening-closing net. Adult females (1-155 ind./m³) showed a clear normal DVM pattern throughout the entire water column in spring, whereas adultmales did notmigrate. DVM of copepodite V (CV) individuals was not clear, but the maximum abundance of CI-CIV occurred consistently in the upper 10-20 m layer, where there was a high concentration of chlorophyll-a (Chl-a) (0.49-1.19 μg/L). In summer, weak DVM was limited to coldwaters beneath the thermocline for adult females (<30 ind./m³), but not for adult males. The maximum abundance of CI-CIV also occurred consistently in the subsurface layer (20-40 m) together with high concentrations of Chl-a (0.81-2.36 μg/L). CV individuals (1-272 ind./m³) moved slightly up ward nocturnally to the near-surface layer (10-20 m), where the average temperature was 25.74℃, but they were not found in the surface layer (0-10m; 28.31℃). These results indicate that the existence of the YSBCW affected food availability at depth and the vertical temperature distribution, leading to variation in the amplitude and shape of stage-specific vertical distributions (CI to adults) in C. sinicus before and during the formation of cold waters in the Yellow Sea during the study period.
- Yellow Sea Cold BottomWater (YSCBW),
- copepod,
- Calanus sinicus,
- developmental stages,
- diel vertical migration (DVM)

FullText(HTML)

References(29)

References

ChiharaM,MuranoM. 1997. An Illustrated Guide to Marine Plankton in Japan: Tokyo: Tokai University Press, 1574

Dagg M J. 1985. The effects of food limitation on diel migratory behavior in marine zooplankton. Ergebnisse der Limnologie, 21: 247-255

DaggM J, Frost B W, Newton J A. 1997. Vertical migration and feeding behavior of Calanus pacificus females during a phytoplankton bloom in Dabob Bay. U S Limnology and Oceanography, 42(5): 974-980

Haney J F. 1988. Diel patterns of zooplankton behavior. Bulletin of Marine Science, 43(3): 583-603

Hays G C, Kennedy H, Frost B W. 2001. Individual variability in diel vertical migration of a marine copepod: Why some individuals remain at depth when othersmigrate. Limnology and Oceanography, 46(8): 2050-2054

Huang C, Uye S, Onbe T. 1992. Ontogenic diel vertical migration of the planktonic copepod Calanus sinicus in the Inland Sea of Japan: II. Late fall and early spring. Marine Biology, 113: 391-400

Huang C, Uye S, Onbe T. 1993. Ontogenetic diel vertical migration of the planktonic copepod Calanus sinicus in the Inland Sea of Japan: III. Early summer and overall seasonal pattern. Marine Biology, 117: 289-299

JangMC, Kim W-S. 1998. Zooplankton distribution and environmental characteristics of the Yellow Sea in spring, 1996. Ocean and Polar Research, 20: 19-28

Kang J-H, Kim W-S. 2008. Spring dominant copepods and their distribution pattern in the Yellow Sea. Ocean and Science Journal, 43(2): 67-79

Kang J-H, Kim W-S, Chang K-I, et al. 2004. Distribution of plankton related to the mesoscale physical structure within the surface mixed layer in the southwestern East Sea, Korea. Journal of Plankton Research, 26(12): 1515-1528

Kang J-H, Kim W-S, Jeong H J, et al. 2008. Why did the copepod Calanus sinicus increase during the 1990s in the Yellow Sea?. Marine Environmental Research, 63: 82-90

Kim W-S, Kang J-H. 2001. Zooplankton found in the stomach of the fishes captures in the Yellow Sea in May and August of 1999. In:Korean YSLME, eds. Proceedings of the Korean YSLME Workshop, Its Experience and Future Contribution, February 26-27. Seoul: MOMAF & KORDI, 103-116

Lampert W. 1989. The adaptive significance of diel vertical migration of zooplankton. Functional Ecology, 3: 21-27

Liu Hui-Lian, Sun Song. 2010. Diel vertical distribution andmigration of a euphausiid Euphausia pacifica in the Southern Yellow Sea. Deep-Sea Research II, 57: 594-605

Marine Zooplankton Colloquium;

2 (MZC2). 2001. Future marine zooplankton research—a perspective. Marine Ecology Progress Series, 222: 297-308

McLaren I A. 1963. Effects of temperature on growth of zooplankton and the adaptive value of vertical migration. Journal of the Fisheries Research Board of Canada, 26: 199-220

Morioka Y, Shinohara F, Nakashima J, et al. 1991. A diel vertical migration of the copepod Calanus sinicus in relation to welldeveloped thermocline in the Yellow Sea, October 1987. Bulletin of the Seikai National Fisheries Research Institute, 69: 79-86

Osgood K E, Checkley Jr D M. 1997. Observations of a deep aggregation of Calanus pacificus in the Santa Barbara Basin. Limnology and Oceanography, 42(5): 997-1001

Paffenhöfer G A, Lee T N, Sherman B K. 1987. Summer upwelling on the southeastern continental shelf of the USA during 1981. Abundance, distribution and patch formation of zooplankton. Progress in Oceanography, 19: 403-436

ParkC. 1997. Seasonal distribution, egg production and feeding by the marine copepod Calanus sinicus in Asan Bay, Korea. Journal of The Korean Society of Oceanography, 32(2): 85-92

Parsons T R, Maita Y, Lalli C M. 1984. A Manual of chemical and biological methods for seawater analysis. New York: Pergamon Press, 173

Pu Xin-Ming, Sun Song, Yang Bo, et al. 2004a. The combined effects of temperature and food supply on Calanus sinicus in the southern Yellow Sea in summer. Journal of Plankton Research, 26(9): 1049-1057

Pu Xin-Ming, Sun Song, Yang Bo, et al. 2004b. Life history strategies of Calanus sinicus in the southern Yellow Sea in summer. Journal of Plankton Research, 26(9): 1059-1068

Uye S. 2000. Why does Calanus sinicus prosper in the shelf ecosystem of the Northwest Pacific Ocean? ICES Journal ofMarine Science, 57: 1850-1855

Uye S, Huang C, Onbe T. 1990. Ontogenic diel vertical migration of the planktonic copepod Calanus sinicus in the Inland Sea of Japan. Marine Biology, 104: 389-396

Wang Rong, Zuo Tao, Wang Ke. 2003. The Yellow Sea Cold Bottom Water—-an oversummering site for Calanus sinicus (Copepoda, Crustacea). Journal of Plankton Research, 25: 169-183

Williamson C E, Sanders R W, Moeller R E, et al. 1996. Utilization of subsurface food resources for zooplankton reproduction: Implications for diel vertical migration theory. Limnology and Oceanography, 41: 224-233

Zhao Xu, Hamre J, Li Feng, et al. 2003. Recruitment, sustainable yield and possible ecological consequences of the sharp decline of the anchovy (Engraulis japonicus) stock in the Yellow Sea in the 1990s. Fisheries Oceanography, 12: 495-501

Relative Articles

Supplements(0)

Cited By

Proportional views