Long-term climate change in the Mediterranean region in the midst of decadal variability
详细信息 查看全文
- 作者:Annarita Mariotti ; Yutong Pan ; Ning Zeng ; Andrea Alessandri
- 关键词:Climate change ; Decadal climate variability ; Mediterranean region ; CMIP5 models
- 刊名:Climate Dynamics
- 出版年:2015
- 出版时间:March 2015
- 年:2015
- 卷:44
- 期:5-6
- 页码:1437-1456
- 全文大小:3,033 KB
- 参考文献:1. Adler, RF, Huffman, GJ, Chang, A, Ferraro, R, Xie, P, Janowiak, J, Rudolf, B, Schneider, U, Curtis, S, Bolvin, D, Gruber, A, Susskind, J, Arkin, P (2003) The version 2 global precipitation climatology project (GPCP) monthly precipitation analysis (1979–Present). J Hydrometeorol 4: pp. 1147-1167 CrossRef
2. Alessandri, A, Felice, M, Zeng, N, Mariotti, A, Pan, Y, Cherchi, A, Lee, J-Y, Wang, B, Ha, K-J, Ruti, P, Artale, V (2014) Robust assessment of the expansion and retreat of Mediterranean climate in the 21st century. Nat Sci Rep.
3. Alkama, R, Decharme, B, Douville, H, Becker, M, Cazenave, A, Sheffield, J, Voldoire, A, Tyteca, S, Moigne, P (2010) Global evaluation of the ISBA-TRIP continental hydrologic system. Part 1: a twofold constraint using GRACE terrestrial water storage estimates and in situ river discharges. J Hydrometeorol 11: pp. 583-600 CrossRef
4. Ammann, CM, Meehl, GA, Washington, WM (2003) A monthly and latitudinally varying volcanic forcing dataset in simulations of 20th century climate. Geophys Res Lett 30: pp. 1657 CrossRef
5. Barkhordarian, A, Storch, H, Bhend, J (2013) The expectation of future precipitation change over the Mediterranean region is different from what we observe. Clim Dyn 40: pp. 225-244 CrossRef
6. Blade, I, Liebmann, B, Fortuny, D (2012) Observed and simulated impacts of the summer NAO in Europe: implications for projected drying in the Mediterranean region. Clim Dyn 39: pp. 709-727 CrossRef
7. Boberg, F, Christensen, JH (2012) Overestimation of Mediterranean summer temperature projections due to model deficiencies. Nat Clim Change 2: pp. 433-436 CrossRef
8. Booth, BBB, Dunstone, NJ, Halloran, PR, Andrews, T, Bellouin, N (2012) Aerosols implicated as a prime driver of twentieth-century North Atlantic climate variability. Nature 484: pp. 228-232 CrossRef
9. Delworth, TL, Ramaswamy, V, Stenchikov, GL (2005) The impact of aerosols on simulated ocean temperature and heat content in the 20th century. Geophys Res Lett 473: pp. L24709 CrossRef
10. Ding, Y, Carton, JA, Chepurin, GA, Stenchikov, G, Robock, A, Sentman, LT, Krastin, JP (2014) Ocean response to volcanic eruptions in Coupled Model Intercomparison Project 5 simulations. J Geophys Res.
11. Douville, H, Decharme, B, Ribes, A, Alkama, R, Sheffield, J (2012) Anthropogenic influence on multi-decadal changes in reconstructed global evapotranspiration. Nat Clim Change.
12. Driscoll, S, Bozzo, A, Gray, LJ, Robock, A, Stenchikov, G (2012) Coupled Model Intercomparison Project 5 (CMIP5) simulations of climate following volcanic eruptions. J Geophys Res.
13. Dubois, C, Somot, S, Calmanti, S (2012) Future projections of the surface heat and water budgets of the Mediterranean Sea in an ensemble of coupled atmosphere–ocean regional climate models. Clim Dyn 39: pp. 3125 CrossRef
14. Duchon, CE (1979) Lanczos filter in one and two dimensions. J Appl Meteorol 18: pp. 1016-1022 CrossRef
15. Fenoglio-Marc, L, Mariotti, A, Sannino, G, Meyssignac, B, Carillo, A, Struglia, MV, Rixen, M (2013) Decadal variability of net water flux at the Mediterranean Sea Gibraltar Strait. Glob Planet Change 100: pp. 1-10 CrossRef
16. Giorgi, F (2006) Climate change hot-spots. Geophys Res Lett 33: pp. L08707
17. Giorgi, F, Bi, X (2009) Time of emergence (TOE) of GHG-forced precipitation change hot-spots. Geophys Res Lett 36: pp. L06709
18. Giorgi, F, Lionello, P (2008) Climate change projections for the Mediterranean region. Glob Planet Change 63: pp. 90-104
文摘
Long-term climate change and decadal variability in the Mediterranean region during 1860-100 are investigated based on observational data and the newly available Coupled Model Intercomparison Project—Phase 5 (CMIP5) experiments. Observational records show that decadal variability and a general tendency for annual-mean conditions to be warmer and drier have characterized the Mediterranean during 1860-005. Consistency with CMIP5 model simulations including greenhouse gases (GHG), as well as anthropogenic aerosols and natural forcings, suggest that forced changes have characterized aspects of Mediterranean climate during this period. Future GHG-forced change will take place in the midst of decadal variability, both internal and forced, as it has occurred in the past. However, future rates of forced warming and drying over the Mediterranean are projected to be higher than in the past century. The degree to which forced change and internal variability will matter depends on the climatic quantity being considered. For surface air temperature and Mediterranean Sea annual-mean evaporation and surface freshwater fluxes, variability and forced change have become comparable and the forced signal has already emerged from internal variability. For quantities with large internal variability and relatively small forced signal such as precipitation, forced change will emerge later on in the twenty-first century over selected regions and seasons. Regardless, the probability distribution of future precipitation anomalies is progressively shifting towards drier conditions. Overall, results highlight that both mean projected forced change and the variability that will accompany forced mean change should be considered in the development of future climate outlooks.