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Assessment of Changes in Temperature and Primary Production over the East China Sea and South Sea during the 21st Century using an Earth System Model
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  • Journal title : Ocean and Polar Research
  • Volume 34, Issue 2,  2012, pp.229-237
  • Publisher : Korea Institute of Ocean Science & Technology
  • DOI : 10.4217/OPR.2012.34.2.229
 Title & Authors
Assessment of Changes in Temperature and Primary Production over the East China Sea and South Sea during the 21st Century using an Earth System Model
Park, Young-Gyu; Choi, Sang-Hwa; Kim, Seon-Dong; Kim, Cheol-Ho;
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Using results from an Earth System model, we investigated change in primary production in the East China Sea, under a global warming scenario. As global warming progresses, the vertical stratification of water becomes stronger, and nutrient supply from the lower part to the upper part is reduced. Consequently, so is the primary production. In addition to the warming trend, there is strong decadal to interdecadal scale variability, and it takes a few decades before the warming trend surpasses natural variability. Thus, it would be very hard to investigate the global warming trend using data of several years` length.
East China Sea;biogeochemical modeling;primary production;
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한국습지학회지, 2016. vol.18. 3, pp.313-323 crossref(new window)
Assessment of the Impact of Climate Change on Marine Ecosystem in the South Sea of Korea II, Ocean and Polar Research, 2013, 35, 2, 123  crossref(new windwow)
Water temperature assessment on the small ecological stream under climate change, Journal of Wetlands Research, 2016, 18, 3, 313  crossref(new windwow)
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민홍식, 김철호 (2006) 한국연안 표층수온의 경년변동과 장기변화. Ocean and Polar Res 28(4):415-423 crossref(new window)

박영규, 최상화, 김철호 (2011) 지구시스템모형을 이용한 황동중국해 이산화탄소분압 분포 특성 평가. Ocean and Polar Res 33(4):447-455 crossref(new window)

Bopp L, Monfray P, Aumont O, Dufresne JL, Le Treut H, Madec G, Terray L, Orr JC (2001) Potential impact of climate change on marine export productions. Global Biogeochem Cy 5:81-99

Brodeur RD, Mills CE, Overland JE, Walters GE, Schumacher, JD (1999) Evidence for a substantial increase in gelatinous zooplankton in the Bering Sea, with possible links to climate change. Fish Oceanogr 8:296-306 crossref(new window)

Delworth TL, Broccoli AJ, Rosati A, Stouffer RJ, Balaji V, Beesley JA, Cooke WF, Dixon KW, Dunne J, Dunne KA, Durachta JW, Findell KL, Ginoux P, Gnanadesikan A, Gordon CT, Griffies SM, Gudgel R, Harrison MJ, Held IM, Hemler RS, Horowitz RW, Klein SA, Knutson TR, Kushner PJ, Langenhorst AR, Lee HC, Lin SJ, Lu J, Malyshev SL, Milly PCD, Ramaswamy V, Russell J, Schwarzkopf MD, Shevliakova E, Sirutis JJ, Spelman MJ, Stern WF, Winton M, Wittenberg AT, Wyman B, Zeng F, Zhang R (2006) GFDL's CM2 global coupled climate models. part I: Formulation and simulation characteristics. J Climate 19:643-674. doi:10.1175/JCLI3629.1 crossref(new window)

Dunne JP, Armstrong RA, Gnanadesikan A, Sarmiento JL (2005) Empirical and mechanistic models for the particle export ratio. Global Biogeochem Cy 19:GB4026. doi: 10.1029/2004GB002390 crossref(new window)

Dunne JP, Gnanadesikan A, Sarmiento JL, Slater RD (2010) Technical description of the prototype version (v0) of Tracers Of Phytoplankton with Allometric Zooplankton (TOPAZ) ocean biogeochemical model as used in the Princeton IFMIP model. Biogeosci Disc 6:10381-10446 supplement

Gnanadesikan A, Dixon KW, Griffies SM, Balaji V, Barreiro M, Beesley JA, Cooke WF, Delworth TL, Gerdes R, Harrison MJ, Held IM, Hurlin WJ, Lee HC, Liang Z, Nong G, Pacanowsky RC, Rosati A, Russell J, Samuels BL, Song Q, Spelman MJ, Stouffer RJ, Sweeney CO, Vecchi G, Winton M, Wittenberg AT, Zeng F, Zhang R, Dunne JP (2006) GFDL's CM2 Global Coupled Climate Models. Part II: the baseline ocean simulation. J Climate 19:675-697. doi:10.1175/JC LI3630.1 crossref(new window)

Hill DK (1995) Pacific warming unsettles ecosystems. Science 267:1911-1912 crossref(new window)

Hoegh-Guldberg O, Bruno, JF (2010) The Impact of Climate Change on the World's Marine Ecosystems. Science 328:1523-1528. doi:10.1126/science.1189930 crossref(new window)

Ito A, Kawamiya M (2010) Potential impact of ocean ecosystem changes due to global warming on marine organic carbon aerosols. Global Biogeochem Cy 24: GB1012. doi:10.1029/2009GB003559 crossref(new window)

Keller AA, Klein-MacPhee G (2000) Impact of elevated temperature on the growth, survival, and trophic dynamics of winter flounder larvae: a mesocosm study. Can J Fish Aquat Sci 57:2382-2392 crossref(new window)

Sarmiento JL, Slater RD, Junne J, Gnanadesikan A, Hiscock MR (2010) Efficiency of small scale carbon mitigation by patch iron fertilization. Biogeosciences 7:3593-3624 crossref(new window)

Walther GR, Post E, Convey P, Menzel A, Parmesan C, Beebee TJC, Fromentin TM, Hoegh-Guldberg O, Bairlein F (2002) Ecological responses to recent climate change. Nature 416:389-395 crossref(new window)