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Zooplankton community size-structure change and mesh size selection under the thermal stress caused by a power plant in a semi-enclosed bay

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Abstract

Zooplankton samples were collected using 505, 160 and 77 µm mesh nets around a power plant during four seasons in 2011. We measured total length of zooplankton and divided zooplankton into seven size classes in order to explore how zooplankton community size-structure might be altered by thermal discharge from power plant. The total length of zooplankton varied from 93.7 to 40 074.7 µm. The spatial distribution of mesozooplankton (200 −2 000 µm) populations were rarely affected by thermal discharge, while macro- (2 000 −10 000 µm) and megalo-zooplankton (>10 000 µm) had an obvious tendency to migrate away from the outfall of power plant. Thus, zooplankton community tended to become smaller and biodiversity reduced close to power plant. Moreover, we compared the zooplankton communities in three different mesh size nets. Species richness, abundance, evenness index and Shannon-Wiener diversity index of the 505 µm mesh size were significantly lower than those recorded from the 160 and 77 µm mesh size. Average zooplankton abundance was highest in the 77 µm mesh net ((27 690.0±1 633.7) ind./m3), followed by 160 µm mesh net ((9 531.1±1 079.5) ind./m3), and lowest in 505 µm mesh net ((494.4±104.7) ind./m3). The ANOSIM and SIMPER tests confirmed that these differences were mainly due to small zooplankton and early developmental stages of zooplankton. It is the first time to use the 77 µm mesh net to sample zooplankton in such an environment. The 77 µm mesh net had the overwhelming abundance of the copepod genus Oithona, as an order of magnitude greater than recorded for 160 µm mesh net and 100% loss through the 505 µm mesh net. These results indicate that the use of a small or even multiple sampling net is necessary to accurately quantify entire zooplankton community around coastal power plant.

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References

  • Alden R W. 1979. Effects of a thermal discharge on the mortality of copepods in a subtropical estuary. Environmental Pollution, 20(1): 3–19, doi: https://doi.org/10.1016/0013-9327(79)90049-1

    Google Scholar 

  • Antacli J C, Hernández D, Sabatini M E. 2010. Estimating copepods’ abundance with paired nets: Implications of mesh size for population studies. Journal of Sea Research, 63(1): 71–77, doi: https://doi.org/10.1016/j.seares.2009.09.004

    Google Scholar 

  • Bamber R N. 1995. The influence of rising background temperature on the effects of marine thermal effluents. Journal of Thermal Biology, 20(1-2): 105–110, doi: https://doi.org/10.1016/0306-4565(94)00038-K

  • Bernhard M, Möller F, Nassogne A, et al. 1973. Influence of pore size of plankton nets and towing speed on the sampling performance of two high-speed samplers (Delfino I and II) and its consequences for the assessment of plankton populations. Marine Biology, 20(2): 109–136, doi: https://doi.org/10.1007/BF00351450

    Google Scholar 

  • Chew L L, Chong V C, Wong R C S, et al. 2015. Three decades of sea water abstraction by Kapar power plant (Malaysia): What impacts on tropical zooplankton community?. Marine Pollution Bulletin, 101(1): 69–84, doi: https://doi.org/10.1016/j.marpolbul.2015.11.022

    Google Scholar 

  • Clarke K R, Gorley R N, Somerfield P J, et al. 2014. Change in Marine Communities: An Approach to Statistical Analysis and Interpretation. Plymouth, UK: Primer-E Ltd, 256

    Google Scholar 

  • Cushing D H, Humphrey G F, Banse K, et al. 1958. Report of the committee on terms and equivalents. Rapp P-V. Réun Cons Int Explor Scient Mer Méditerr, 144: 15–16

    Google Scholar 

  • Davies R M, Jensen L D. 1975. Zooplankton entrainment at three mid-Atlantic power plants. Journal-Water Pollution Control Federation, 47(8): 2130–2142

    Google Scholar 

  • Du Xiuning, Wang Yunlong, Chen Tao, et al. 2013. Seasonal variation of zooplankton copepod community in Xiangshan Bay of East China. Chinese Journal of Ecology (in Chinese), 32(10): 2756–2763

    Google Scholar 

  • Du Xiuning, Wang Yunlong. 2014. Inter-annual and seasonal changes of zooplankton biomass and species in the specific region of the Xiangshan Bay. Marine Science Bulletin (in Chinese), 33(3): 293–298

    Google Scholar 

  • Du Ping, Xu Xiaoqun, Liu Jingjing, et al. 2015. Spatial heterogeneity of macro-and meso-zooplankton in Xiangshan Bay in spring and summer. Acta Ecologica Sinica (in Chinese), 35(7): 2308–2321, doi: https://doi.org/10.5846/stxb201306091487

    Google Scholar 

  • Du Ping, Xu Xiaoqun, Xu Xudan, et al. 2017. Effects of three different aquaculture activities on zooplankton community in Xiangshan Bay. Journal of Fisheries of China (in Chinese), 41(11): 1719–1733

    Google Scholar 

  • Dussart B M. 1965. Les différentes catégories de plancton. Hydrobiologia, 26(1): 72–74, doi: https://doi.org/10.1007/BF00142255

    Google Scholar 

  • Evans M S, Warren G J, Page D I. 1986. The effects of power plant passage on zooplankton mortalities: Eight years of study at the Donald C. Cook nuclear plant. Water Research, 20(6): 725–734, doi: https://doi.org/10.1016/0043-1354(86)90096-5

    Google Scholar 

  • Gallienne C P, Robins D B. 2001. Is Oithona the most important copepod in the world’s oceans?. Journal of Plankton Research, 23(12): 1421–1432, doi: https://doi.org/10.1093/plankt/23.12.1421

    Google Scholar 

  • Hwang J S, Kumar R, Dahms H U, et al. 2007. Mesh size affects abundance estimates of Oithona spp. (Copepoda, Cyclopoida). Crustaceana, 80(7): 827–837, doi: https://doi.org/10.1163/156854007781363169

    Google Scholar 

  • Jiang Zhibing, Zeng Jiangning, Chen Quanzhen, et al. 2009. Potential impact of rising seawater temperature on copepods due to coastal power plants in subtropical areas. Journal of Experimental Marine Biology and Ecology, 368(2): 196–201, doi: https://doi.org/10.1016/j.jembe.2008.10.016

    Google Scholar 

  • Jiang Zhibing, Chen Quanzhen, Zeng Jiangning, et al. 2012. Phytoplankton community distribution in relation to environmental parameters in three aquaculture systems in a Chinese subtropical eutrophic bay. Marine Ecology Progress Series, 446: 73–89, doi: https://doi.org/10.3354/meps09499

    Google Scholar 

  • Jones K J, Gowen R J. 1990. Influence of stratification and irradiance regime on summer phytoplankton composition in coastal and shelf seas of the British Isles. Estuarine, Coastal and Shelf Science, 30(6): 557–567, doi: https://doi.org/10.1016/0272-7714(90)90092-6

    Google Scholar 

  • Laws E A, Falkowski P G, Smith Jr W O, et al. 2000. Temperature effects on export production in the open ocean. Global Biogeochemical Cycles, 14(4): 1231–1246, doi: https://doi.org/10.1029/1999GB001229

    Google Scholar 

  • Liu Zilin, Cai Yuming, Ning Xiuren. 1998. The distribution of chlorophyll a and primary productivity in the middle and west of Xiangshan Bay. Donghai Marine Science (in Chinese), 16(3): 18–24

    Google Scholar 

  • Liu Zhensheng, Wang Chunsheng, Yang Junyi, et al. 2004. Distribution of zooplankton in the Xiangshangang Bay in winter. Donghai Marine Science (in Chinese), 22(1): 34–42

    Google Scholar 

  • Lloyd P, Plagányi É E, Weeks S J, et al. 2011. Ocean warming alters species abundance patterns and increases species diversity in an African sub-tropical reef-fish community. Fisheries Oceanography, 21(1): 78–94, doi: https://doi.org/10.1111/j.1365-2419.2011.00610.x

    Google Scholar 

  • Mäkinen K, Vuorinen I, Hänninen J. 2017. Climate-induced hydrography change favours small-bodied zooplankton in a coastal ecosystem. Hydrobiologia, 792(1): 83–96, doi: https://doi.org/10.1007/s10750-016-3046-6

    Google Scholar 

  • Miao Qingsheng, Zhou Liangming, Deng Zhaoqing. 2010. Numerical simulation and in-situ measurement for heat discharge from Xiangshangang power plant Into Sea. Coastal Engineering, 29(4): 1–11

    Google Scholar 

  • Nielsen T G, Sabatini M. 1996. Role of cyclopoid copepods Oithona spp. in North Sea plankton communities. Marine Ecology Progress Series, 139: 79–93, doi: https://doi.org/10.3354/meps139079

    Google Scholar 

  • Pansera M, Granata A, Guglielmo L, et al. 2014. How does mesh-size selection reshape the description of zooplankton community structure in coastal lakes?. Estuarine, Coastal and Shelf Science, 151: 221–235, doi: https://doi.org/10.1016/j.ecss.2014.10.015

    Google Scholar 

  • Porter K G. 1973. Selective grazing and differential digestion of algae by zooplankton. Nature, 244(5412): 179–180, doi: https://doi.org/10.1038/244179a0

    Google Scholar 

  • Riccardi N. 2010. Selectivity of plankton nets over mesozooplankton taxa: implications for abundance, biomass and diversity estimation. Journal of Limnology, 69(2): 287–296, doi: https://doi.org/10.4081/jlimnol.2010.287

    Google Scholar 

  • Rice E, Dam H G, Stewart G. 2015. Impact of climate change on estuarine zooplankton: surface water warming in long island sound is associated with changes in copepod size and community structure. Estuaries and Coasts, 38(1): 13–23, doi: https://doi.org/10.1007/s12237-014-9770-0

    Google Scholar 

  • Stabeno P J, Kachel N B, Moore S E, et al. 2012. Comparison of warm and cold years on the southeastern Bering Sea shelf and some implications for the ecosystem. Deep Sea Research Part II: Topical Studies in Oceanography, 65–70: 31–45, doi: https://doi.org/10.1016/j.dsr2.2012.02.020

    Google Scholar 

  • Şundri M I, Gomoiu M T. 2009. Qualitative and quantitative structure of zooplankton asociations in the Danube thermal discharge area of Nuclear Power Plant Cernavoda. Geoecomarina, 15: 123–130

    Google Scholar 

  • Tseng L C, Dahms H U, Hung J J, et al. 2011. Can different mesh sizes affect the results of copepod community studies?. Journal of Experimental Marine Biology and Ecology, 398(1-2): 47–55, doi: https://doi.org/10.1016/j.jembe.2010.12.007

    Google Scholar 

  • Tunowski J. 2009. Changes in zooplankton abundance and community structure in the cooling channel system of the Konin and Pątnów power plants. Fisheries & Aquatic Life, 17(4): 279–289, doi: https://doi.org/10.2478/v10086-009-0020-1

    Google Scholar 

  • Turner J T. 2004. The importance of small planktonic copepods and their roles in pelagic marine food webs. Zoological Studies, 43(2): 255–266

    Google Scholar 

  • Vannucci M. 1968. Loss of organisms through the meshes. In: Tranter D J, ed. Zooplankton Sampling. UNESCO Monographs on Oceanographic Methodology. Paris: UNESCO Press, 77–86

    Google Scholar 

  • Wang Chunsheng, Liu Zhensheng, He Dehuai. 2003. Seasonal dynamics of zooplankton biomass and abundance in Xiangshan Bay. Journal of Fisheries of China (in Chinese), 27(6): 595–599

    Google Scholar 

  • Wang Xiaobo, Qiu Wusheng, Qin Mingli, et al. 2009. Studies on ecological community distribution of zooplankton in Xiangshan Bay. Marine Environmental Science (in Chinese), 28(1): 62–64

    Google Scholar 

  • Wang Yangcai, Wu Xiongfei, Shi Huixiong, et al. 2011. Study on zooplankton communities near coastal power plants in Xiangshan Bay. Journal of Ningbo University (Natural Science & Engineering Edition) (in Chinese), 24(3): 5–10

    Google Scholar 

  • Xu Zhaoli, Chen Yaqu. 1989. Aggregated intensity of dominant species of zooplankton in autumn in the East China Sea and Yellow Sea. Journal of Ecology (in Chinese), 8(4): 13–15

    Google Scholar 

  • Yvon-Durocher G, Montoya J M, Trimmer M, et al. 2011. Warming alters the size spectrum and shifts the distribution of biomass in freshwater ecosystems. Global Change Biology, 17(4): 1681–1694, doi: https://doi.org/10.1111/j.1365-2486.2010.02321.x

    Google Scholar 

  • Zheng Zhong, Li Song, Li Shaojing, et al. 1982. Pelagic Copepoda in China Seas (in Chinese). Shanghai: Shanghai Science and Technology Press, 1–162

    Google Scholar 

  • Zheng Zhong, Li Shaojing, Xu Zhenzu, et al. 1984. Marine Planktology (in Chinese). Beijing: China Ocean Press, 1–653

    Google Scholar 

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Acknowledgements

We thank the captain and crew of R/V Ocean for assistance with samplings. We also thank LetPub for linguistic assistance during manuscript preparation.

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Correspondence to Yifeng Zhu or Xiaojun Yan.

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Foundation item: The National Key Research and Development Program of China under contract No. 2018YFD0900702; the K.C. Wong Magna Fund in Ningbo University (SS).

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Shao, Q., Zhu, Y., Dai, M. et al. Zooplankton community size-structure change and mesh size selection under the thermal stress caused by a power plant in a semi-enclosed bay. Acta Oceanol. Sin. 39, 62–70 (2020). https://doi.org/10.1007/s13131-020-1634-9

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  • DOI: https://doi.org/10.1007/s13131-020-1634-9

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