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科学通报 2011

上新世中期海洋表面温度变化及其与古气候重建数据对比

, PP. 423-432

燕青,张仲石,王会军,姜大膀,郑伟鹏

Keywords: 上新世中期,海洋表面温度,永久的El,Ni？,o,数值模拟,剧烈增温

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Abstract:

上新世中期,过去约3.29~2.97Ma之间,是地质历史上距今最近的一个持续性暖期.它与模式预测的21世纪末地球系统最有可能达到的气候态具有一定的可比性.因此,研究该时期气候变化对于理解全球变暖背景下的气候变化趋势具有重要的参考作用.采用最新的PRISM3重建数据集,利用FOAM耦合模式开展了上新世中期的全球气候模拟,并对上新世中期次极地北大西洋剧烈增暖和“永久的ElNi？o”两个热点问题进行了讨论.模拟结果表明与工业革命前相比,上新世中期年平均海洋表面温度(SST)升高了2.3℃,中高纬度海洋的增温幅度大于低纬度海洋,赤道太平洋SST东西梯度减小以及大西洋经向翻转环流减弱.在SST变化的空间格局上,模拟结果与重建结果基本一致.FOAM也能较好地模拟出北大西洋、北太平洋以及南美西海岸的显著增暖,但模拟的次极地北大西洋和赤道太平洋SST的变化与重建数据仍有差别.上述重建与模拟的差异是由古气候数据重建的不确定性、上新世中期模拟的困难以及模式本身的不完善共同造成的.

References

[1]	An Z S, Huang Y S, Liu W G, et al. Multiple expansions of C4 plant biomass in East Asia since 7 Ma coupled with strengthened monsooncirculation. Geology, 2005, 33: 705-708
[2]	Ding Z L, Derbyshire E, Yang S L, et al. Stacked 2[J].6-Ma grain size record from the Chinese loess based on five sections and correlationwith the deep-sea δ18O record. Paleoceanography.2002, 17:1033-
[3]	Guo Z T, Ruddiman W F, Hao Q Z, et al. Onset of Asian desertification by 22 Ma ago inferred from loess deposits in China. Nature, 2002,416: 159-163
[4]	Wang Y J, Cheng H, Edwards R L, et al. A high-resolution absolute-dated late Pleistocene monsoon record from Hulu Cave, China.Science, 2001, 294: 2345-2348
[5]	方小敏, 赵志军, 李吉均, 等. 祁连山北缘老君庙背斜晚新生代磁性地层与高原北部隆升. 中国科学D 辑: 地球科学, 2004, 34:97-106
[6]	吴乃琴, Rousseau D D, 刘秀平. 25 万年来黄土蜗牛的生态演替对地球轨道变化的响应[J].科学通报.2000, 45:765-770？？浏览
[7]	朱敏, 丁仲礼, 王旭, 等. 南阳盆地PETM 事件的高分辨率碳同位素记录[J].科学通报.2010, 55:2400-2405？？浏览
[8]	Jiang D B, Wang H J, Drange H, et al. Last glacial maximum over China: Sensitivities of climate to paleovegetation and Tibetan ice sheet.J Geophys Res, 2003, 108: 4102, doi: 10.1029/2002JD002167
[9]	周波涛, 赵平. 古东亚冬季风和夏季风反位相变化吗[J].科学通报.2009, 54:3136-3143？？浏览
[10]	Haywood A M, Valdes P J. Modelling Pliocene warmth: Contribution of atmosphere, oceans and cryosphere. Earth Planet Sci Lett, 2004,218: 363-377
[11]	Bonham S G, Haywood A M, Lunt D J, et al. El Ni?o-Southern Oscillation, Pliocene climate and equifinality. Phil Trans R Soc A, 2009,367: 127-156
[12]	Lunt D J, Haywood A M, Schmidt G A, et al. Earth system sensitivity inferred from Pliocene modelling and data. Nature Geoscience,2010, 3: 60-64
[13]	Jacob R L. Low frequency variability in a simulated atmosphere ocean system. Dissertation for the Doctoral Degree. Wisconsin:University of Wisconsin-Madison, 1997
[14]	Liu Z, Otto-Bliesner B, Kutzbach J, et al. Coupled climate simulation of the evolution of global monsoons in the Holocene. J Clim, 2003,16: 2472-2490
[15]	Boville B, Gent P. The NCAR climate system model, version one. J Clim, 1998, 11: 1115-1130
[16]	Otto-Bliesner B, Brady E. Tropical Pacific variability in the NCAR climate system model. J Clim, 2001, 14: 3587-3607
[17]	Liu Z, Kutzbach J, Wu L. Modeling climate shift of El Ni？o variability in the Holocene. Geophys Res Lett, 2000, 27: 2265-2268
[18]	Lee S Y, Poulsen C J. Sea ice control of Plio-Pleistocene tropical Pacific climate evolution. Earth Planet Sci Lett, 2006, 248: 253-262
[19]	Liu Z, Wang Y, Gallimore R, et al. Simulating the transient evolution and abrupt change of Northern Africa atmosphere-ocean-terrestrialecosystem in the Holocene. Quat Sci Rev, 2007, 26: 1818-1837
[20]	Liu Z, Wang Y, Gallimore R, et al. On the cause of abrupt vegetation collapse in North Africa during the Holocene: Climate variability vs.vegetation feedback. Geophys Res Lett, 2006, 33: L22709, doi:10.1029/2006GL028062
[21]	Notaro M, Wang Y, Liu Z, et al. Combined statistical and dynamical assessment of simulated vegetation-rainfall interactions in NorthAfrica during the mid-Holocene. Glob Change Biol, 2008, 14: 347-368
[22]	Pierrehumbert R T. High levels of atmospheric carbon dioxide necessary for the termination of global glaciation. Nature, 2004, 429:646-649
[23]	Wang Y, Notaro M, Liu Z, et al. Detecting vegetation-precipitation feedbacks in mid-Holocene North Africa from two climate models.Clim Past, 2008, 4: 59-67
[24]	ETOPO2v2 Global Gridded 2-minute Database. National Geophysical Data Center, National Oceanic and Atmospheric Administration,US Dept of Commerce, http://www.ngdc.noaa.gov/mgg/global/etopo2.html, 2006
[25]	Sohl L E, Chandler M A, Schmunk R B, et al. PRISM3/GISS topographic reconstruction. US Geol Surv Data Series 419, 2009
[26]	Edwards M. Global Gridded Elevation and Bathymetry. In: Kineman J J, Ohrenschall M A, eds. Global Ecosystems Database, Version 1.0(on CD-ROM), Documentation Manual, DISC-A: National Geophysical Data Center, Key to Geophysical Records Documentation No. 26(Incorporated in: Global Change Database, Volume 1), Boulder, CO, National Oceanic and Atmospheric Administration, 1992, A14-1 toA14-4,
[27]	Bryan F O. Climate drift in a multicentury integration of the NCAR climate system model. J Clim, 1998, 11: 1455-1471
[28]	Reynolds R W, Smith T M. A high-resolution global sea surface temperature climatology. J Clim, 1995, 8: 1571-1583
[29]	Brierley C M, Fedorov A V, Liu Z H, et al. Greatly expanded tropical warm pool and weakened hadley circulation in the early Pliocene.Science, 2009, 323: 1714-1718
[30]	Dowsett H J, Robinson M M. Mid-Pliocene equatorial Pacific sea surface temperature reconstruction: A multi-proxy perspective. PhilTrans R Soc A, 2009, 367: 109-125
[31]	Haywood A M, Dekens P, Ravelo A C, et al. Warmer tropics during the mid-Pliocene? Evidence from alkenone paleothermometry and afully coupled ocean-atmosphere GCM. Geochem Geophys Geosyst, 2005, 6: Q03010, doi: 10.1029/2004GC000799
[32]	Ravelo A C, Dekens P S, McCarthy M. Evidence for El Ni?o-like conditions during the Pliocene. GSA Today, 2006, 16: 4-11
[33]	Andersson C. Transfer function vs. modern analog technique for estimating Pliocene sea-surface temperatures based on plankticforaminiferal data, western Equatorial Pacific Ocean. J Foramin Res, 1997, 27: 123-132
[34]	Dowsett H J. Faunal re-evaluation of mid-Pliocene conditions in the western Equatorial Pacific. Micropaleontology, 2007, 53: 447-456
[35]	Siesser W. Pliocene paleoclimatology at ODP site 1115, Solomon sea (southwestern Pacific ocean), based on calcareous nannofossils. In:Huchon P, Taylor B, Klaus A, eds. Process Ocean Drill Program, Science Results, 2001, 180: 1-15
[36]	Haywood A M, Valdes P J, Peck V L. A permanent El Ni?o-like state during the Pliocene? Paleoceanography, 2007, 22: PA1213, doi:10.1029/2006PA001323
[37]	Wright J D, Miller K G. Control of North Atlantic deep water circulation by the Greenland-Scotland Ridge. Paleoceanography, 1996, 11:157-170
[38]	Sriver R L, Huber M. Observational evidence for an ocean heat pump induced by tropical cyclones. Nature, 2007, 447: 577-580
[39]	Fedorov A V, Brierley C M, Emanuel K. Tropical cyclones and permanent El Ni?o in the early Pliocene epoch. Nature, 2010, 463:1066-1070
[40]	Raymo M E, Grant B, Horowitz M, et al. Mid-Pliocene warmth: Stronger greenhouse and stronger conveyor. Mar Micropaleontol, 1996,27: 313-326
[41]	Ravelo A V, Andreasen D H. Enhanced circulation during a warm period. Geophys Res Lett, 2000, 27: 1001-1004
[42]	Hodell D A, Venz-Curtis K A. Late Neogene history of deepwater ventilation in the southern ocean. Geochem Geophys Geosyst, 2006, 7:Q09001, doi:10.1029/2005GC001211
[43]	Meehl G A, Stocker T F, Collins W D, et al. Global Climate Projections. In: Solomon S, Qin D, Manning M, et al, eds. Climate Change2007: The Physical Science Basis. Contribution of working group I to the Fourth Assessment Report of the Intergovernmental Panel onClimate Change. Cambridge and New York: Cambridge University Press, 2007
[44]	Liu X D, Yin Z Y. Sensitivity of East Asian monsoon climate to the uplift of the Tibetan Plateau. Palaeogeogr Palaeoclimatol Palaeoecol,2002, 183: 223-245
[45]	Wang H J. Role of vegetation and soil in the Holocene megathermal climate over China. J Geophys Res, 1999, 104: 9361-9367
[46]	Zhang Z S, Wang H J, Guo Z T, et al. What triggers the transition of palaeoenvironmental patterns in China, the Tibetan Plateau uplift orthe Paratethys sea retreat[J].Palaeogeogr Palaeoclimatol Palaeoecol.2007, 245:317-331
[47]	Wang Y, Roulet N T, Frolking S, et al. The importance of Northern Peatlands in global carbon systems during the Holocene. Clim PastDiscuss, 2009, 5: 683-693
[48]	Wang Y, Mysak L A, Roulet N T. Holocene climate and carbon cycle dynamics: Experiments with the “green” McGill paleoclimatemodel. Glob Biogeochem Cycle, 2005, 19: GB3022, doi: 10.1029/2005GB002484
[49]	程军, Liu Z Y, He F, 等. 温盐环流在百年尺度上影响中国气候的一个数值模拟证据[J].科学通报.2010, 55:2406-2412？？浏览
[50]	Brovkin V, Kim J, Hofmann M, et al. A lowering effect of reconstructed Holocene changes in sea surface temperatures on the atmosphericCO2 concentration. Glob Biogeochem Cycle, 2008, 22: GB1016, doi: 10.1029/2006GB002885
[51]	Berggren W A, Kent D V, Swisher C C, et al. A revised Cenozoic geochronology and chronostratigraphy. In: Berggren W A, Kent D V,Aubry M P, et al, eds. Geochronology, Time Scales and Global Stratigraphic Correlation. Soc Sed Geol Spec Pub, 1995, 54: 129-212
[52]	Jansen E.[J].Overpeck J, Briffa K R, et al. Palaeoclimate. In: Solomon S, Qin D, Manning M, et al, eds. Climate Change 2007: The PhysicalScience Basis. Contribution of Working Group Ι to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change.Cambridge and New York: Cambridge University Press.2007,:-
[53]	Dowsett H J, Thompson R, Barron J, et al. Joint investigations of the middle Pliocene climate Ι: PRISM paleoenvironmentalreconstructions. Glob Planet Change, 1994, 9: 169-195
[54]	Dowsett H J, Barron J A, Poore R Z. Middle Pliocene sea surface temperatures: A global reconstruction. Mar Micropaleontol, 1996, 27:13-25
[55]	Dowsett H J, Barron J A, Poore R Z, et al. Middle Pliocene paleoenvironmental reconstruction : PRISM2. US Geol Surv Open File Rep,1999. 99-535
[56]	Dowsett H J. The PRISM palaeoclimate reconstruction and Pliocene sea-surface temperature. In: Williams M, Haywood A M, Gregory J,et al, eds. Deep-time Perspectives on Climate Change: Marrying the Signal from Computer Models and Biological Proxies. London:Micropalaeontological Society, Special Publication, 2007. 459-480
[57]	Salzmann U, Haywood A M, Lunt D J, et al. A new global biome reconstruction and data-model comparison for the middle Pliocene. GlobEcol Biogeogr, 2008, 17: 432-447
[58]	Dowsett H J, Robinson M M, Foley K M. Pliocene three-dimensional global ocean temperature reconstruction. Clim Past Discuss, 2009, 5:1901-1928
[59]	Dowsett H J, Cronin T M, Poore R Z, et al. Micropaleontological evidence for increased meridional heat transport in the North AtlanticOcean during the Pliocene. Science, 1992, 258: 1133-1135
[60]	Fedorov A V, Dekens P S, McCarthy M, et al. The Pliocene paradox (mechanisms for a permanent El Ni?o). Science, 2006, 312:1485-1489
[61]	Wara W M, Ravelo A C, Delaney L M. Permanent El Ni？o-like conditions during the Pliocene warm period. Science, 2005, 309: 758-761
[62]	Rickaby R E, Halloran P. Cool La Ni?a during the warmth of the Pliocene? Science, 2005, 307: 1948-1952
[63]	Chandler M, Rind D, Robert T. Joint investigations of the middle Pliocene climate II: GISS GCM Northern Hemisphere results. GlobPlanet Change, 1994, 9: 197-219
[64]	Sloan L C, Crowley T J, Pollard D. Modeling of middle Pliocene climate with the NCAR GENESIS general circulation model. MarMicropaleontol, 1996, 27: 51-61
[65]	Haywood A M, Valdes P J, Sellwood B W, et al. Modelling middle Pliocene warm climates of the USA. Palaeontol Electron, 2001, 4:1-21
[66]	Haywood A M, Valdes P J, Sellwood B W. Global scale palaeoclimate reconstruction of the middle Pliocene climate using the UKMOGCM: Initial results. Global Planet Change, 2000, 25: 239-256
[67]	Jiang D B, Wang H J, Ding Z L, et al. Modeling the middle Pliocene climate with a global atmospheric general circulation model. JGeophys Res, 2005, 110: D14107, doi:10.1029/2004JD005639
[68]	Cunningham S A, Kanzow T, Rayner D, et al. Temporal variability of the Atlantic Meridional Overturning Circulation at 26.5°N. Science,2007, 317: 935-938

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