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NTIS 바로가기바다 : 한국해양학회지 = The sea : the journal of the Korean society of oceanography, v.28 no.1, 2023년, pp.1 - 18
이호준 (해군사관학교 해양학과) , 남성현 (서울대학교 자연과학대학 지구환경과학부)
The East Sea, one of the regions where the most rapid warming is occurring, is known to have important implications for the response of the ocean to future climate changes because it not only reacts sensitively to climate change but also has a much shorter turnover time (hundreds of years) than the ...
Belkin, I.M., 2009. Rapid warming of large marine ecosystems. Prog. Oceanogr., 81(1-4): 207-213.
Bryden, H.L., H.R. Longworth and S.A. Cunningham, 2005. Slowing of the Atlantic meridional overturning circulation at?25°N. Nature, 438(7068): 655-657.
Chang, K.I., K. Kim, Y.B. Kim, W.J. Teague, J.C. Lee and J.H. Lee, 2009. Deep flow and transport through the Ulleung?Interplain Gap in the southwestern East/Japan Sea. Deep Sea Res. Part I Oceanogr. Res. Pap., 56(1): 61-72.
Chang, K.I., N.G. Hogg, M.S. Suk, S.K. Byun, Y.G. Kim and K. Kim, 2002. Mean flow and variability in the southwestern?East Sea. Deep Sea Res. Part I Oceanogr. Res. Pap., 49(12): 2261-2279.
Chang, K.I., W.J. Teague, S.J. Lyu, H.T. Perkins, D.K. Lee, D.R. Watts, Y.B. Kim, D.A. Mitchell, C.M. Lee and K. Kim, 2004. Circulation and currents in the southwestern East/Japan Sea: Overview and review. Prog. Oceanogr., 61(2-4): 105-156.
Chen, C.T.A., A.S. Bychkov, S.L. Wang and G.Y. Pavlova, 1999. An anoxic Sea of Japan by the year 2200?. Mar. Chem.,?67(3-4): 249-265.
Choi, Y.J. and J.H. Yoon, 2010. Structure and seasonal variability of the deep mean circulation of the East Sea (Sea of Japan).?J. Oceanogr., 66(3): 349-361.
Clayson, C.A. and M. Luneva, 2004. Deep convection in the Japan (East) Sea: A modeling perspective. Geophys. Res. Lett.,?31(17).
Cui, Y. and T. Senjyu, 2010. Interdecadal oscillations in the Japan Sea proper water related to the arctic oscillation. J.?Oceanogr., 66(3): 337-348.
Cui, Y. and T. Senjyu, 2012. Has the upper portion of the Japan Sea Proper Water formation really been enhancing?. J.?Oceanogr., 68(4): 593-598.
Dickson, B., I. Yashayaev, J. Meincke, B. Turrell, S. Dye and J. Holfort, 2002. Rapid freshening of the deep North Atlantic?Ocean over the past four decades. Nature, 416(6883): 832-837.
Gamo, T. and Y. Horibe, 1983. Abyssal circulation in the Japan Sea. J. Oceanogr. Soc. Jpn., 39(5): 220-230.
Gamo, T., 1999. Global warming may have slowed down the deep conveyor belt of a marginal sea of the northwestern?Pacific: Japan Sea. Geophys. Res. Lett., 26(20): 3137-3140.
Gamo, T., 2011. Dissolved oxygen in the bottom water of the Sea of Japan as a sensitive alarm for global climate change.?Trends Analyt Chem, 30(8): 1308-1319.
Gamo, T., N. Momoshima and S. Tolmachyov, 2001. Recent upward shift of the deep convection system in the Japan Sea, as?inferred from the geochemical tracers tritium, oxygen, and nutrients. Geophys. Res. Lett., 28(21): 4143-4146.
Han, M., Y.K. Cho, H.W. Kang and S. Nam, 2020. Decadal changes in meridional overturning circulation in the East Sea?(Sea of Japan). J. Phys. Oceanogr., 50(6): 1773-1791.
Han, M., Y.S. Chang, H.W. Kang, D.J. Kang and Y.S. Kim, 2021. Turnover time of the East Sea (Sea of Japan) meridional?overturning circulation. Front. Mar. Sci., 8.
Jamet, Q., W.K. Dewar, N. Wienders, B. Deremble, S. Close and T. Penduff, 2020. Locally and remotely forced subtropical?AMOC variability: a matter of time scales. J. Clim., 33(12): 5155-5172.
Jeong, Y., S. Nam, J.I. Kwon, U. Uppara and Y.H. Jo, 2022. Surface Warming Slowdown with Continued Subsurface?Warming in the East Sea (Japan Sea) over Recent Decades (2000-2014). Front. Mar. Sci., 173.
Kang, D.J., J.Y. Kim, T. Lee and K.R. Kim, 2004. Will the East/Japan Sea become an anoxic sea in the next century?. Mar.?Chem., 91(1-4): 77-84.
Kang, D.J., S. Park, Y.G. Kim, K. Kim and K.R. Kim, 2003. A moving-boundary box model (MBBM) for oceans in change:?An application to the East/Japan Sea. Geophys. Res. Lett., 30(6).
Kim, B.-G., Y.-K. Cho and Y. Noh, 2022a. Deep convection along the continental slope in the East/Japan Sea: A large-eddy?simulation study. Front. Mar. Sci., 9:824256.
Kim, H., N. Hirose and K. Takayama, 2022b. Physical and Biological Factors Underlying Long-Term Decline of Dissolved?Oxygen Concentration in the East/Japan Sea. Front. Mar. Sci., 9: 851598.
Kim, K., K.R. Kim, D.H. Min, Y. Volkov, J.H. Yoon and M. Takematsu, 2001. Warming and structural changes in the East?(Japan) Sea: a clue to future changes in global oceans?. Geophys. Res. Lett., 28(17): 3293-3296.
Kim, K., K.R. Kim, Y.G. Kim, Y.K. Cho, D.J. Kang, M. Takematsu and Y. Volkov, 2004. Water masses and decadal?variability in the East Sea (Sea of Japan). Prog. Oceanogr., 61(2-4): 157-174.
Kim, K., K.R. Kim, Y.G. Kim, Y.K. Cho, J.Y. Chung, B.H. Choi, S.K. Byun, G.H. Hong, M. Takematsu, J.H. Yoon, Y.?Volkov and M. Danchenkov, 1996. New findings from CREAMS observations: Water masses and eddies in the East Sea.?J. Korean Soc. Oceanogr., 31(4): 155-163.
Kim, K.R. and K. Kim, 1996. What is happening in the East Sea (Japan Sea)?: Recent chemical observations during?CREAMS 93-96. J. Korean Soc. Oceanogr., 31(4): 164-172.
Kim, K.R., G. Kim, K. Kim, V. Lobanov, V. Ponomarev and A. Salyuk, 2002. A sudden bottom-water formation during the?severe winter 2000-2001: The case of the East/Japan Sea. Geophys. Res. Lett., 29(8): 75-1-75-4.
Kim, Y.-B. and G.-T. Yi, 2017. Historical background and its scientific meaning of the Japanese hydrographic survey of the?East Sea in 1932. J. Fis. Mar. Sci. Edu., 29(5): 1373-1383.
Kosugi, N., N. Hirose, T. Toyoda and M. Ishii, 2021. Rapid freshening of Japan Sea Intermediate Water in the 2010s. J?Oceanogr., 77(2): 269-281.
Kumamoto, Y.I., M. Yoneda, Y. Shibata, H. Kume, A. Tanaka, T. Uehiro and K. Shitashima, 1998. Direct observation of the?rapid turnover of the Japan Sea bottom water by means of AMS radiocarbon measurement. Geophys. Res. Lett., 25(5):651-654.
Kwon, Y.O., K. Kim, Y.G. Kim and K.R. Kim, 2004. Diagnosing long-term trends of the water mass properties in the East?Sea (Sea of Japan). Geophys. Res. Lett., 31(20).
Lee, E.Y. and K.A. Park, 2019. Change in the recent warming trend of sea surface temperature in the East Sea (Sea of Japan)?over decades (1982-2018). Remote Sens., 11(22): 2613.
Levin, L.A. and N. Le Bris, 2015. The deep ocean under climate change. Science, 350(6262): 766-768.
Lindsey, R. and L. Dahlman, 2020. Climate Change: Ocean Heat Content. Climate.gov, August, 17.
Marshall, J. and F. Schott, 1999. Open-ocean convection: Observations, theory, and models. Rev. Geophys, 37(1): 1-64.
Min, D.H. and M.J. Warner, 2005. Basin-wide circulation and ventilation study in the East Sea (Sea of Japan) using?chlorofluorocarbon tracers. Deep Sea Res. Part II Top. Stud. Oceanogr., 52(11-13): 1580-1616.
Mooers, C.N., H. Kang, I. Bang and D.P. Snowden, 2006. JES CIRCULATION. Oceanography., 19(3): 86.
Na, T., J. Hwang, S.Y. Kim, S. Jeong, T. Rho and T. Lee, 2022. Large increase in dissolved organic carbon in the East Sea?(Japan Sea) from 1999 to 2019. Front. Mar. Sci., 108. ADD Page number.
Nitani, H., 1972. On the deep and bottom waters in the Japan Sea, in Research in Hydrography and Oceanography, edited by?D. Shoji, pp. 151-201, Hydrogr. Dep. of Jpn. Mar. Safety Agency, Tokyo.
Pai, S.C., G.C. Gong and K.K. Liu, 1993. Determination of dissolved oxygen in seawater by direct spectrophotometry of?total iodine. Mar. Chem., 41(4): 343-351.
Park, K.A., K. Kim, P.C. Cornillon and J.Y. Chung, 2006. Relationship between satellite-observed cold water along the?Primorye coast and sea ice in the East Sea (the Sea of Japan). Geophys. Res. Lett., 33(10).
Park, Y.G., 2007. The effects of Tsushima Warm Current on the interdecadal variability of the East/Japan Sea thermohaline?circulation. Geophys. Res. Lett., 34(6).
Postlethwaite, C.F., E.J. Rohling, W.J. Jenkins and C.F. Walker, 2005. A tracer study of ventilation in the Japan/East Sea.?Deep Sea Res. Part II Top. Stud. Oceanogr., 52(11-13): 1684-1704.
Send, U., M. Lankhorst and T. Kanzow, 2011. Observation of decadal change in the Atlantic meridional overturning?circulation using 10 years of continuous transport data. Geophys. Res. Lett., 38(24).
Senjyu, T. and H. Sudo, 1993. Water characteristics and circulation of the upper portion of the Japan Sea Proper Water. J.?Mar. Syst., 4(4): 349-362.
Senjyu, T. and H. Sudo, 1994. The upper portion of the Japan Sea Proper Water; its source and circulation as deduced from?isopycnal analysis. J. Oceanogr., 50(6): 663-690.
Senjyu, T., 2022. Changes in Mid-Depth Water Mass Ventilation in the Japan Sea Deduced From Long-Term Spatiotemporal?Variations of Warming Trends. Front. Mar. Sci.
Senjyu, T., H.R. Shin, J.H. Yoon, Z. Nagano, H.S. An, S.K. Byun and C.K. Lee, 2005. Deep flow field in the Japan/East Sea?as deduced from direct current measurements. Deep Sea Res. Part II Top. Stud. Oceanogr., 52(11-13): 1726-1741.
Senjyu, T., T. Aramaki, S. Otosaka, O. Togawa, M. Danchenkov, E. Karasev and Y. Volkov, 2002. Renewal of the bottom?water after the winter 2000-2001 may spin-up the thermohaline circulation in the Japan Sea. Geophys. Res. Lett., 29(7): 53-1-53-3.
Shin, J., S. Noh and S. Nam, 2020. Intraseasonal abyssal current variability of bottom-trapped topographic Rossby waves in?the Southwestern East Sea (Japan Sea). Front. Mar. Sci., 7: 579680.
Srokosz, M., M. Baringer, H. Bryden, S. Cunningham, T. Delworth, S. Lozier, J. Marotzke and R. Sutton, 2012. Past, present,?and future changes in the Atlantic meridional overturning circulation. Bull Am Meteorol Soc, 93(11): 1663-1676.
Stouffer, R.J., J. Yin, J.M. Gregory, K.W. Dixon, M.J. Spelman, W. Hurlin, A.J. Weaver, M. Eby, G.M. Flato, H. Hasumi,?A. Hu, J.H. Jungclaus, I.V. Kamenkovich, A. Levermann, M. Montoya, S. Murakami, S. Nawrath, A. Oka, W.R. Peltier,?D.Y. Robitaille, A. Sokolov, G. Vettoretti and S.L. Weber, 2006. Investigating the causes of the response of the?thermohaline circulation to past and future climate changes. J. Clim., 19(8): 1365-1387.
Sudo, H., 1986. A note on the Japan Sea proper water. Prog. Oceanogr., 17(3-4): 313-336.
Talley, L., D.H. Min, V. Lobanov, V. Luchin, V. Ponomarev, A. Salyuk, A. Shcherbina, P. Tishchenko and I. Zhabin, 2006.?Japan/East Sea water masses and their relation to the sea's circulation. Oceanography., 19(3): 32-49.
Talley, L.D., V. Lobanov, V. Ponomarev, A. Salyuk, P. Tishchenko, I. Zhabin and S. Riser, 2003. Deep convection and brine?rejection in the Japan Sea. Geophys. Res. Lett., 30(4).
Tanaka, K., 2014. Formation of bottom water and its variability in the northwestern part of the Sea of Japan. J. Geophys. Res.?Oceans, 119(3): 2081-2094.
Teague, W.J., K.L. Tracey, D.R. Watts, J.W. Book, K.I. Chang, P.J. Hogan, D.A. Mitchell, M.S. Suk, M. Wimbush and J.H.?Yoon, 2005. Observed deep circulation in the Ulleung Basin. Deep Sea Res. Part II Top. Stud. Oceanogr., 52(11-13):?1802-1826.
Tsunogai, S., Y.W. Watanabe, K. Harada, S. Watanabe, S. Saito and M. Nakajima, 1993. Dynamics of the Japan Sea deep?water studied with chemical and radiochemical tracers. In Elsevier oceanography series, Vol. 59, Elsevier, pp. 105-119.
Uda, M., 1934. The results of simultaneous oceanographic investigations in the Japan Sea and its adjacent waters in May and?June, 1932. J. Imp. Fish. Exp. Stn., 5: 57-190.
Worthington, E.L., B.I. Moat, D.A. Smeed, J.V. Mecking, R. Marsh and G.D. McCarthy, 2021. A 30-year reconstruction of?the Atlantic meridional overturning circulation shows no decline. Ocean Sci., 17(1): 285-299.
Yoon, S.T., K.I. Chang, S. Nam, T. Rho, D.J. Kang, T. Lee, K.A. Park, V. Lobanov, D. Kaplunenko, P. Tishchenko and K.R.?Kim, 2018. Re-initiation of bottom water formation in the East Sea (Japan Sea) in a warming world. Sci. Rep., 8(1): 1-10.
Yoshikawa, Y., T. Awaji and K. Akitomo, 1999. Formation and circulation processes of intermediate water in the Japan Sea.?J. Phys. Oceanogr., 29(8): 1701-1722.
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