探討氣候模式在全球暖化下與聖嬰現象相似之顯著熱帶太平洋海溫暖化反應

Hung-Yi Tseng; 曾弘毅

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/49223

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	黃彥婷
dc.contributor.author	Hung-Yi Tseng	en
dc.contributor.author	曾弘毅	zh_TW
dc.date.accessioned	2021-06-15T11:19:53Z	-
dc.date.available	2017-10-05
dc.date.copyright	2016-10-05
dc.date.issued	2016
dc.date.submitted	2016-08-19
dc.identifier.citation	Alexander, M. A., I. Blade, M. Newman, J. R. Lanzante., N. -C. Lau, and J. D. Scott, 2002: The atmospheric bridge: the influence of ENSO teleconnections on air–sea interaction over the global oceans. J. Climate 15, 2205 – 2231. Andrews, T., J. M. Gregory, M. J. Webb, and K. E. Taylor, 2012: Forcing, feedbacks and climate sensitivity in CMIP5 atmosphere–ocean climate models. Geophys. Res. Lett. 39, L09712. Barnett, T. P., M. Latif, E. Kirk, and E. Roeckner, 1991: On ENSO physics. J. Climate, 4, 487–515. Block, K., and T. Mauritsen ,2013: Forcing and feedback in the MPI-ESM-LR coupled model under abruptly quadrupled CO2, J. Adv. Model. Earth Syst., 5(4), 676–691. Bjerknes, J., 1969: Atmospheric teleconnections from the equatorial pacific. Journal of Physical Oceanography, 97(3), 163-172. Caldwell, P.M., M. D. Zelinka, K. E. Taylor, and K. Marvel, 2016: Quantifying the sources of inter-model spread in equilibrium climate sensitivity. J Climate 29, 513–524. Cane, M. A., A. C. Clement, A. Kaplan, Y. Kushnir, R. Murtugudde, D. Pozdnyakov, R. Seager, and S. E. Zebiak, 1997: 20th century sea surface temperature trends, Science, 275, 957–960. Chang, C. -P., Y. Zhang, and T. Li, 2000: Interannual and interdecadal variations of the East Asian summer monsoon and tropical Pacific SSTs. Part I: roles of the subtropical ridge. J Climate, 13, 4310–4325. Chou, C. and J. D. Neelin, 2004: Mechanisms of global warming impacts on regional tropical precipitation. J. Climate, 17, 2688-2701. Clement, A. C., R. Seager, M. A. Cane, and S. E. Zebiak, 1996: An ocean dynamical thermostat, J. Climate, 9, 2190–2196. Collins, M., and Coauthors, 2005: 'El Nino- or La Nina-like climate change?.” Climate Dynamics, 24, 89-104. Grose, M. R., J. Bhend, S. Narsey, A. Sen Gupta, and J. R. Brown, 2014b: Can we constrain CMIP5 rainfall projections in the tropical Pacific based on surface warming patterns? J. Climate, 27, 9123–9138. Held, I. M., and B. J. Soden, 2006: Robust responses of the hydrological cycle to global warming. J. Climate, 19, 5686– 5699. Huang, P., S.-P. Xie, K. Hu, G. Huang, and R. Huang, 2013: Patterns of the seasonal response of tropical rainfall to global warming. Nature Geosci., 6, 357–361. Johnson, N. C. and Xie, S. -P., 2010: Changes in the sea surface temperature threshold for tropical convection. Nature Geosci. 3, 842–845. Kim, S. B., T. Lee, and I. Fukumori, 2007: Mechanisms controlling the interannual variation of mixed layer temperature averaged over the Nino-3 region, J. Climate, 20, 3822–3843. Knutson, T. R., and S. Manabe, 1995: Time-mean response over the tropical Pacific due to increased CO2 in a coupled ocean–atmosphere model. J. Climate, 8, 2181–2199. L’Heureux, M. L., S. Lee, and B. Lyon, 2013: Recent multidecadal strengthening of the Walker circulation across the tropical Pacific. Nature Clim. Change 3, 571–576. Li G., and S. -P. Xie, 2014: Tropical biases in CMIP5 multimodel ensemble: the excessive equatorial Pacific cold tongue and double ITCZ problems. J. Clim. 27: 1765–1780. Li, G., S.-P. Xie, Y. Du, and Y. Luo, 2016: Effects of excessive equatorial cold tongue bias on the projections of tropical Pacific climate change. Part I: the warming pattern in CMIP5 multi-model ensemble. Climate Dynamics. Lin, J.L., 2007: The double-ITCZ problem in IPCC AR4 coupled GCMs: ocean-atmosphere feedback analysis. J Climate, 20, 4497–4525. Lindzen, R. S., and S. Nigam, 1987: On the role of sea surface temperature gradients in forcing low-level winds and convergence in the tropics. J. Atmos. Sci.,44, 2418–2436 Liu, Z., S. Vavrus, F. He, N. Wen, and Y. Zhong, 2005: Rethinking tropical ocean response to global warming: The enhanced equatorial warming. J. Climate, 18, 4684–4700. Ma, J., and S.-P. Xie, 2013: Regional patterns of sea surface temperature change: A source of uncertainty in future projections of precipitation and atmospheric circulation. J. Climate, 26, 2482-2501. Meehl, G. A., and W. M. Washington, 1996: El Nino-like climate change in a model with increased atmospheric CO2 concentrations. Nature, 382, 56–60. Misra, V., L. Marx, M. Fennessey, B. Kirtman, and J. L. Kinter III, 2008: A comparison of climate prediction and simulation over tropical Pacific. J. Climate, 21, 3601–3611 Rayner, N. A., D. E. Parker, E. B. Horton, C. K. Folland, L. V. Alexander, D. P. Rowell, E. C. Kent, and A. Kaplan, 2003: Global analyses of sea surface temperature, sea ice, and night marine air temperature since the late nineteenth century. J. Geophys. Res., 108, 4407. Schlosser ,C.A., and P. R. Houser, 2007: Assessing a satellite-era perspective of the global water cycle. J Clim, 20(7), 1316–1338. Seager, R., and R. Murtugudde, 1997: Ocean dynamics, thermocline adjustment, and regulation of tropical SST. J. Climate, 10, 521–534. Stephens, G. L., J. Li, M. Wild, C. A. Clayson, N. Loeb, S. Kato, T. L’Ecuyer, P. W. Stackhouse Jr., M. Lebsock, and T. Andrews, 2012: An update on Earth’s energy balance in light of the latest global observations. Natural Geosci, 5, 691–696. Tokinaga, H., S. -P. Xie, C. Deser, Y. Kosaka, and Y. M. Okumura, 2012: Slowdown of the Walker circulation driven by tropical Indo-Pacific warming. Nature, 491, 439–443. Trenberth, K. E., 2015: Has there been a hiatus? Science 349, 691–692. Trenberth K. E., J. T. Fasullo, and J. Kiehl, 2009: Earth’s global energy budget. Bull. Am. Meteorol. Soc. 90(3), 311–324. Vecchi, G. A., B. J. Soden, A. T. Wittenberg, I. M. Held, A. Leetmaa, and M. J. Harrison, 2006: Weakening of tropical Pacific atmospheric circulation due to anthropogenic forcing. Nature, 441, 73–76. Vial, J., Dufresne, J. -L. Dufrense, and S. Bony, 2013: On the interpretation of inter model spread in CMIP5 climate sensitivity estimates. Climate Dynamics, 41, 3339. Wang, C. Z., 2002a: Atmospheric circulation cells associated with the El Nino-Southern Oscillation. J. Climate, 15, 399–419. Wang H, A. Kumar, W. Wang, and Y. Xue, 2012: Influence of ENSO on Pacific decadal variability: an analysis based on the NCEP climate forecast system. J. Climate, 25, 6136–6151. Xie, S.-P., C. Deser, G. A. Vecchi, J. Ma, H. Teng, and A. T. Wittenberg, 2010: Global warming pattern formation: Sea surface temperature and rainfall. J. Climate, 23, 966–986. Ying, J., P. Huang, and R. Huang, 2016: Evaluating the formation mechanisms of the equatorial Pacific SST warming pattern in CMIP5 models. Adv. Atmos. Sci., 33, 433–441. Yu, L., X. Jin, and R. A. Weller, 2008: Multidecade global flux datasets from the Objectively Analyzed Air–Sea Fluxes (OAFlux) Project: Latent and sensible heat fluxes, ocean evaporation, and related surface meteorological variables. Woods Hole Oceanographic Institution OAFlux Project Tech. Rep. OA-2008-01, 64 pp. Zhang, C., 1993: Large-scale variability of atmospheric deep convection in relation to sea surface temperature in the tropics. J. Climate. 6, 1898–1913. Zhang, L., and T. Li, 2014: A simple analytical model for understanding the formation of sea surface temperature patterns under global warming. J. Climate, 27, 8413–8421. Zhang Q, A. Kumar, Y. Xue, W. Wang, and F. F. Jin, 2007: Analysis of the ENSO cycle in the NCEP coupled forecast model. J. Climate, 40, 1265–1284.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/49223	-
dc.description.abstract	熱帶太平洋地區的海表溫度變異可對氣候造成相當程度的影響，例如：沃克環流的強度、哈德利胞以及熱帶邊緣地區沙漠的擴張、以及熱帶降雨帶的位移。在全球暖化的情境下，大部份氣候模式認為未來熱帶太平洋地區會呈現類似聖嬰現象發生時的海表溫度變異：赤道地區加強暖化，且東赤道太平洋地區較西赤道太平洋地區暖化更為明顯。然而，由於現今氣候模式存在著氣候場以及聖嬰現象模擬的誤差，許多研究質疑此一暖化趨勢的可信度。本研究的主要目的為探討此海表溫度暖化結構的形成機制以及評估其可信度。透過地表的能量收支分析，我們發現與現今氣候蒸發場相關且在赤道地區較弱的蒸發抑制機制、以及主要為水氣作用在赤道地區較強的向下長波輻射，為氣候模式中造成此一暖化結構的主要原因。另外，我們認為：(1)現今氣候場的誤差也可能導致未來氣候模擬的偏差，以及(2)全球暖化與聖嬰現象的形成機制並不相同，但有類似的氣候回饋機制。根據本研究的結果，透過修正現今海表溫度及能量收支的氣候場以及對聖嬰現象的模擬，能使我們對氣候模式模擬的未來海溫暖化的量值與結構更有把握。	zh_TW
dc.description.abstract	Sea surface temperature anomaly (SSTA) in tropical Pacific region has been suggested to account for some significant climate changes, for instance, the weakening of Walker circulation, the expansion of the Hadley cell edges and subtropical deserts, and the shift of tropical rainband. Under global warming, most global climate models (GCMs) project an El Nino-like SST warming pattern, with enhanced warming in equatorial region, and a reduced zonal SST gradient along the equator. However, some previous studies have questioned the reliability of these robust responses across GCMs, since most GCMs experience difficulties simulating the observed climatology and ENSO variability in the tropical Pacific. The goal of this thesis is to evaluate the confidence of such El Nino-like SSTA pattern in tropical Pacific region among most GCMs through understanding its formation mechanisms. We demonstrate that the reduced evaporative damping related with the structure of climatological evaporation and the enhanced greenhouse effect related with increasing water vapor over the equatorial central Pacific, are the two major contributors to the SSTA pattern. Furthermore, it is suggested that (1) the biases of present day climatology in GCM simulations may lead to an error of future SST projection, and (2) the global warming scenario and El Nino events share some common atmospheric climate feedbacks, despite the distinct triggering mechanisms. The results set the foundations to evaluate our confidence of the projected SSTA in each GCM by performing a process-based comparison with the observational and reanalysis data.	en
dc.description.provenance	Made available in DSpace on 2021-06-15T11:19:53Z (GMT). No. of bitstreams: 1 ntu-105-R03229013-1.pdf: 10869360 bytes, checksum: 1ebea9c1ec3a5faba4fa93484ec0f7b5 (MD5) Previous issue date: 2016	en
dc.description.tableofcontents	Abstract p.III Abstract (Chinese) p.IV Figure Captions p.6 1. Introduction p.9 1.1 The Importance of Tropical Pacific Sea Surface Temperature p.9 1.2 Projected Changes in Tropical Pacific SST Patterns under Global Warming p.10 1.3 Evaluating the Confidence of the Projected SST Changes p.12 1.4 A Path Forward p.13 2. Data and Methodology p.15 2.1. Data p.15 2.2. Definitions of Domains and Regions p.15 2.3. Definitions of ENSO/warming events p.16 2.4. Surface Energy Budget Analysis p.16 2.5. Measuring the effect of the “Forcing Terms” and the “Response Term” p.19 2.6. Radiation Kernel Method p.22 3. Results and Discussions p.24 3.1 Total SSTA p.24 3.2 SSTA Induced by the Response Term p.25 3.3 SSTA Induced by Shortwave Radiation Changes p.26 3.4 SSTA Induced by Downward Longwave Radiation Changes p.27 3.5 SSTA Induced by Atmospheric Latent and Sensible Heat Flux p.28 3.6 SSTA Induced by Ocean Dynamics p.29 3.7 Discussions p.30 4. Summary and Outlook p.33 Reference p.36 Tables p.41 Figures p.44 Supplementary Figures p.60
dc.language.iso	en
dc.subject	聖嬰現象	zh_TW
dc.subject	海表溫度	zh_TW
dc.subject	全球暖化	zh_TW
dc.subject	熱帶太平洋	zh_TW
dc.subject	氣候模式	zh_TW
dc.subject	tropical Pacific	en
dc.subject	ENSO	en
dc.subject	CMIP5 models	en
dc.subject	sea surface temperature (SST)	en
dc.subject	global warming	en
dc.title	探討氣候模式在全球暖化下與聖嬰現象相似之顯著熱帶太平洋海溫暖化反應	zh_TW
dc.title	Investigation of the Robust El Nino-like Tropical Pacific Sea Surface Temperature Response to Global Warming in CMIP5 Models	en
dc.type	Thesis
dc.date.schoolyear	104-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	許晃雄,羅敏輝,陳維婷
dc.subject.keyword	海表溫度,全球暖化,熱帶太平洋,氣候模式,聖嬰現象,	zh_TW
dc.subject.keyword	sea surface temperature (SST),global warming,tropical Pacific,CMIP5 models,ENSO,	en
dc.relation.page	65
dc.identifier.doi	10.6342/NTU201603134
dc.rights.note	有償授權
dc.date.accepted	2016-08-19
dc.contributor.author-college	理學院	zh_TW
dc.contributor.author-dept	大氣科學研究所	zh_TW
顯示於系所單位：	大氣科學系

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