CHEN Cheng, MAO Zhihua, HAN Guoqi, ZHU Qiankun, GONG Fang, WANG Tianyu. Latitudinal and interannual variations of the spring phytoplankton bloom peak in the East Asian marginal seas[J]. Acta Oceanologica Sinica, 2016, 35(12): 81-88. doi: 10.1007/s13131-016-0867-0
Citation: CHEN Cheng, MAO Zhihua, HAN Guoqi, ZHU Qiankun, GONG Fang, WANG Tianyu. Latitudinal and interannual variations of the spring phytoplankton bloom peak in the East Asian marginal seas[J]. Acta Oceanologica Sinica, 2016, 35(12): 81-88. doi: 10.1007/s13131-016-0867-0

Latitudinal and interannual variations of the spring phytoplankton bloom peak in the East Asian marginal seas

doi: 10.1007/s13131-016-0867-0
  • Received Date: 2015-11-16
  • Rev Recd Date: 2016-05-03
  • Combined studies of latitudinal and interannual variations of annual phytoplankton bloom peak in East Asian marginal seas (17°-58°N, including the northern South China Sea (SCS), Kuroshio waters, the Sea of Japan and the Okhotsk Sea) are rarely. Based on satellite-retrieved ten-year (2003-2012) median timing of the annual Chlorophyll a concentration (Chl a) climax, here we report that this annual spring bloom peak generally delays from the SCS in January to the Okhotsk Sea in June at a rate of (21.20±2.86) km/d (decadal median±SD). Spring bloom is dominant feature of the phytoplankton annual cycle over these regions, except for the SCS which features winter bloom. The fluctuation of the annual peak timing is mainly within ±48 d departured from the decadal median peak date, therefore this period (the decadal median peak date ±48 d) is defined as annual spring bloom period. As sea surface temperature rises, earlier spring bloom peak timing but decreasing averaged Chl a biomass in the spring bloom period due to insufficient light is evident in the Okhotsk Sea from 2003 to 2012. For the rest of three study domains, there are no significant interannual variance trend of the peak timing and the averaged Chl a biomass. Furthermore this change of spring phytoplankton bloom timing and magnitude in the Okhotsk Sea challenges previous prediction that ocean warming would enhance algal productivity at high latitudes.
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  • Chiba S, Aita M N, Tadokoro K, et al. 2008. From climate regime shifts to lower-trophic level phenology:Synthesis of recent progress in retrospective studies of the western North Pacific. Progress in Oceanography, 77(2-3):112-126
    Doney S C. 2006. Plankton in a warmer world. Nature, 444(7120):695-696
    Edwards M, Richardson A J. 2004. Impact of climate change on mar-ine pelagic phenology and trophic mismatch. Nature, 430(7002):881-884
    Esaias W E. 1981. Remote sensing in biological oceanography. Oceanus, 24(3):32-38
    Field C B, Behrenfeld M J, Randerson J T, et al. 1998. Primary produc-tion of the biosphere:integrating terrestrial and oceanic com-ponents. Science, 281(5374):237-240
    Frouin R, Pinker R T. 1995. Estimating Photosynthetically Active Ra-diation (PAR) at the earth's surface from satellite observations. Remote Sensing of Environment, 51(1):98-107
    González Taboada F, Anadón R. 2014. Seasonality of North Atlantic phytoplankton from space:impact of environmental forcing on a changing phenology (1998-2012). Global Change Biology, 20(3):698-712
    Hama T, Shin K H, Handa N. 1997. Spatial variability in the primary productivity in the East China Sea and its adjacent waters. Journal of Oceanography, 53(1):41-51
    Kahru M, Brotas V, Manzano-Sarabia M, et al. 2011. Are phytoplank-ton blooms occurring earlier in the Arctic?. Global Change Bio-logy, 17(4):1733-1739
    Kim S T. 2012. A review of the Sea of Okhotsk ecosystem response to the climate with special emphasis on fish populations. ICES Journal of Marine Science, 69(7):1123-1133
    Koeller P, Fuentes-Yaco C, Platt T, et al. 2009. Basin-scale coherence in phenology of shrimps and phytoplankton in the North At-lantic Ocean. Science, 324(5928):791-793
    Longhurst A. 1995. Seasonal cycles of pelagic production and con-sumption. Progress in Oceanography, 36(2):77-167
    McClain R, Meister C. 2012. Mission Requirements for Future Ocean-Colour Sensors. IOCCG Report, 13:7-8
    Mustapha M A, Saitoh S. 2008. Observations of sea ice interannual variations and spring bloom occurrences at the Japanese scal-lop farming area in the Okhotsk Sea using satellite imageries. Estuarine, Coastal and Shelf Science, 77(4):577-588
    Platt T, Sathyendranath S, White G N, et al. 2010. Diagnostic proper-ties of phytoplankton time series from remote sensing. Estuar-ies and Coasts, 33(2):428-439
    Racault M F, Le Quéré C, Buitenhuis E, et al. 2012. Phytoplankton phenology in the global ocean. Ecological Indicators, 14(1):152-163
    Saitoh S, Iida T, Sasaoka K. 2002. A description of temporal and spa-tial variability in the Bering Sea spring phytoplankton blooms (1997-1999) using satellite multi-sensor remote sensing. Pro-gress in Oceanography, 55(1-2):131-146
    Schwartz M D. 1998. Green-wave phenology. Nature, 394(6696):839-840
    Sherman K, Hempel G. 2009. The UNEP Large Marine Ecosystem Re-port:A perspective on changing conditions in LMEs of the world's Regional Seas. UNEP Regional Seas Report and Studies No. 182. United Nations Environment Programme. Nairobi, Kenya:Elsevier Science BV
    Siegel D A, Doney S C, Yoder J A. 2002. The North Atlantic spring phytoplankton bloom and Sverdrup's critical depth hypothesis. Science, 296(5568):730-733
    Sugisaki H, Hidaka K, Ichikawa T, et al. 2011. Long-term variation of plankton community of Kuroshio warm current area, the spawning ground of Japanese sardine. http://www.pices.int/publications/Sugisaki.pdf[2011-10-23/2015-3-18]
    Tang D L, Ni I H, Kester D R, et al. 1999. Remote sensing observations of winter phytoplankton blooms southwest of the Luzon Strait in the South China Sea. Marine Ecology Progress Series, 191:43-51
    Yamada K, Ishizaka J, Nagata H. 2005. Spatial and temporal variabil-ity of satellite primary production in the Japan Sea from 1998 to 2002. Journal of Oceanography, 61(5):857-869
    Yoder J A, Kennelly M A. 2003. Seasonal and ENSO variability in glob-al ocean phytoplankton chlorophyll derived from 4 years of SeaWiFS measurements. Global Biogeochemical Cycles, 17(4):1112
    Zhai L, Platt T, Tang C, et al. 2011. Phytoplankton phenology on the Scotian Shelf. ICES Journal of Marine Science, 68(4):781-791
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