Abstract
The influence of the NAO on the solar and wind energy resources in the Mediterranean area, in particular, and over the whole North Atlantic area, in general, has been explored based on the analysis of 20 years of reanalysis and satellite data. The analysis was carried out for the winter and annual periods and proved the existence of a marked influence of the NAO pattern on the spatial and temporal variability of the solar and wind energy resources in the study area. Particularly, the NAO signature on the solar/wind energy resources was found to be a north-south dipolar pattern, with the positive/negative centre over the Mediterranean area. Although the spatial patterns obtained are similar, the nature of the relationship obtained for wind energy was found to be less linear and more complex than that attained for solar energy. A composite analysis revealed that interannual variability of the solar and wind energy resources in the Mediterranean area can reach values above 20% in winter and 10% in the annual case associated with changes in the NAO phase. Finally, the analysis of the spatial patterns of the NAO influence on the solar and wind energy resources revealed the existence of spatial and local balancing between these two energy resources in the study area. Results are of interest regarding the estimation of the expected interannual variability of the wind farms and solar plants production in the study region.
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References
Barbour P, Walker S (2008) Wind resource evaluation: Eola Hills. Technical report, Energy Resources Research Laboratory, Department of Mechanical Engineering, Oregon State University, Corvallis, OR
Burlando M (2009) The synoptic-scale surface wind climate regimes of the Mediterranean Sea according to the cluster analysis of ERA-40 wind fields. Theor Appl Climatol 96:69–83
Cassola F, Burlando M, Antonelli M, Corrado FR (2008) Optimization of the regional spatial distribution of wind power plants to minimize the variability of wind energy input into power supply systems. J Appl Meteorol Climatol 47:3099–3116
Chiacchio M, Wild M (2010) Influence of NAO and clouds on long-term seasonal variations of surface solar radiation in Europe. J Geophys Res 115:D00D22. doi:10.1029/2009JD012182
DESERTEC (2010) DESERTEC Red paper. An overview of the DESERTEC concept. DESERTEC organization. http://www.desertec.org/
DLR (2007) TRANS-CSP. DLR-ITT technical report, Köln, Germany
Global Wind Energy Council (2007) Global wind energy council report. http://www.gwec.net/uploads/media/Global_Wind_2007_Report_final.pdf
Hurrell JW, Kushnir Y, Visbeck M, Ottersen G (2003) An overview of the North Atlantic Oscillation. In: Hurrell JW et al (eds) The North Atlantic Oscillation: climate significance and environmental impact. Geophys Monogr Ser, vol 134. AGU, Washington, DC, pp 1–35
IEA (2008) World energy outlook. International Energy Agency, OECD Publication
IEA (2009) Technology roadmap. Wind energy. International Energy, OECD Publication
IEA (2010a) Technology roadmap. Solar photovoltaic energy. International Energy, OECD Publication
IEA (2010b) Technology roadmap. Concentrating solar power. International Energy, OECD Publication
Kempton W, Pimenta FM, Veron DE, Colle BA (2010) Electric power from offshore wind via synoptic-scale interconnection. Proc Natl Acad Sci 107:7240–7245
Lara-Fanego V, Ruiz-Arias JA, Pozo-Vázquez D, Santos-Alamillos F, Tovar-Pescador J (2011) Evaluation of the WRF model solar irradiance forecasts in Andalusia (southern Spain). Sol Energy, doi:10.1016/j.solener.2011.02.014
Li X, Zhong S, Blan X, Hellman WE (2010) Climate and climate variability of the wind power resources in the Great Lakes region of the United States. J Geophys Res 115:D18107. doi:10.1029/2009JD013415
Lohmann S, Schillings C, Mayer B, Meyer R (2006) Long-term variability of solar direct and global radiation derived from ISCCP data and comparison with reanalysis data. Solar Energy 80:1390–1401
Papadimas CD, Fotiadi AK, Hatzianastassiou N, Vardavas I, Bartzokas A (2010) Regional co-variability and teleconnection patterns in surface solar radiation on a planetary scale. Int J Climatol 30:2314–2329
Pozo-Vázquez D, Tovar-Pescador J, Gámiz-Fortis SR, Esteban-Parra MJ, Castro-Díez Y (2004) NAO and solar radiation variability in the European North Atlantic region. Geophys Res Lett 31. doi:10.1029/2003GL018502
Price Water House Coopers (2010) 100% Renewable electricity: a roadmap to 2050 for Europe and North Africa. Price Water House Coopers, London
Pryor S, Barthelmie R, Shoof JT (2006) Inter-annual variability of wind indices across Europe. Wind Energy 9:27–38
Sanchez-Lorenzo A, Calbó J, Brunetti M, Deser C (2009) Dimming/brightening over the Iberian Peninsula: trends in sunshine duration and cloud cover and their relations with atmospheric circulation. J Geophys Res 114:D00D09. doi:10.1029/2008JD011394
Sanchez-Lorenzo A, Calbó J, Martin-Vide J (2008) Spatial and temporal trends in sunshine duration over Western Europe (1938–2004). J Clim 21:6089–6098
Simmons A, Uppala S, Dee D, Kobayashi S (2007) ERA-I: new ECMWF reanalysis products from 1989 onwards. ECMWF Newsletter 110:25–35
Trigo RM, Osborn TJ, Corte-Real JM (2002) The North Atlantic Oscillation influence on Europe: climate impacts and associated physical mechanisms. Clim Res 20:9–17
von Bremen L (2008) Large-scale variability of weather dependent renewable energy sources. In: Troccoli A (ed) Management of weather and climate risk in the energy industry. Springer, The Netherlands, pp 189–205
Weisser D, Foxon T (2003) Implications of seasonal and diurnal variations of wind velocity for power output estimation of a turbine: a case study of Grenada. Int J Energy Res 27:1165–1179
Acknowledgements
The Spanish Ministry of Science and Technology (grant ENE2007-67849-C02-01) and the Andalusian Ministry of Science and Technology (grant P07-RNM-02872) and FEDER funds financed this study. Support is also obtained from the Plan Andaluz de Investigación (Grupo TEP-220). The DLR-ISIS data images were obtained from the Institute of Atmospheric Physics, German Aerospace Center (DLR) (Lohmann, 2006).
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Pozo-Vazquez, D., Santos-Alamillos, F.J., Lara-Fanego, V., Ruiz-Arias, J.A., Tovar-Pescador, J. (2011). The Impact of the NAO on the Solar and Wind Energy Resources in the Mediterranean Area. In: Vicente-Serrano, S., Trigo, R. (eds) Hydrological, Socioeconomic and Ecological Impacts of the North Atlantic Oscillation in the Mediterranean Region. Advances in Global Change Research, vol 46. Springer, Dordrecht. https://doi.org/10.1007/978-94-007-1372-7_15
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