Your search keyword '"Neves, Maria C."' showing total 2 results

1. The response of piezometric levels in Portugal to NAO, EA, and SCAND climate patterns.

Author

Neves, Maria C., Jerez, Sonia, and Trigo, Ricardo M.

Subjects

*RADIATIVE forcing, *PIEZOMETERS, *WATER shortages, *AQUIFERS, *ATMOSPHERIC circulation

Abstract

Highlights • Climate forcing explains 80% of the piezometric level variability in Portugal. • NAO is the leading pattern (40–60% of explained variability) with 6–10 year cycles. • Higher frequency fluctuations (2.5, 3.3 and 4.2 year periods) are linked to EA and SCAND. • EA is more influent in the north and SCAND in the south of the country. • Coupled NAO and EA phases are associated with extreme piezometric levels. Abstract Under the increasing risk of water scarcity, aquifer management strategies can take advantage of a deeper knowledge about the natural long-term fluctuations driven by climate patterns. This study examines the links between major large-scale atmospheric circulation modes and inter-annual to decadal oscillations in groundwater levels in Portugal. Precipitation and piezometric records (1987–2016) from two aquifer systems, Leirosa-Monte Real in the north and Querença-Silves in the south, are analyzed using wavelet transform methods and singular spectral analysis. Wavelet coherences computed between hydrologic time series and the North Atlantic Oscillation (NAO), East Atlantic (EA) and Scandinavia (SCAND) climate patterns show non-stationary relationships that are nonetheless consistent in distinct period bands. The strongest covariability occurs in the 6–10 years band for NAO, in the 2–4 years band for EA (especially after 1999) and in the 4–6 years band for SCAND (mainly after 2005). NAO is the mode playing the most relevant role with a stronger influence in the south (60% on average) than in the north (40% on average). The relatively higher frequency (<5 year period) contributions of EA and SCAND are difficult to set apart but their joint impact accounts for approximately 20% and 40% of the total variance of groundwater levels in the south and north of the country, respectively. Wavelet coherence patterns also expose transitive couplings between NAO, EA and SCAND. Often, coupled phases between climate modes mark abrupt transitions in synchronization patterns and shifts in the time-frequency domain. Extremes in groundwater storage coincide with anti-phase NAO and EA combinations: maximum piezometric levels occur during NAO-EA+ (coincidentally also SCAND+) phases while minimum levels occur during NAO+EA− phases. [ABSTRACT FROM AUTHOR]

Published

2019

2. Climate-driven variability in the context of the water-energy nexus: A case study in southern Portugal.

Author

Neves, Maria C., Malmgren, Katherine, and Neves, Rui Mendonça

Subjects

*ENERGY consumption, *RENEWABLE energy sources, *WATER supply, *NORTH Atlantic oscillation, *WIND power, *SOLAR technology

Abstract

Research on climate-driven variability in the water and energy sectors is required to drive adaptative policies to climate change and boost cross-sectorial synergies. This study addresses the role of the North Atlantic Oscillation (NAO) and East Atlantic pattern (EA) on the water-energy nexus in southern Portugal (Algarve region) from the point of view of water demand, instead of the usual point of view of hydropower production. Water at surface reservoirs and aquifers and solar and wind energy potentials (SP and WP, respectively) do not share the same dominant variability scales, but their interrelationships have implications for leveraging the use of renewable energy in the water sector, particularly through water pumping efficiency gains. Water availability is dominated by interannual fluctuations (70% of the total variance), whereas SP and WP are characterized by seasonal variability scales (98% and 41% of the total variance, respectively). At interannual scales NAO is the main driver of low-frequency variability governing cycles in the 6–8 -year band, whereas fluctuations in the 2–4 -year band are mainly associated with EA. Coupling or synchronizations between opposite phases of NAO and EA correspond to extremes in water availability. Minimum water levels in the summer and during droughts, corresponding to maximum energy demand in the water sector, are clearly connected to synchronized positive NAO and negative EA phases in the preceding winter. Recent advances in the seasonal and long-term predictability of NAO and EA climate patterns can help to improve drought resilience and groundwater sustainability and have huge potential benefits for the water-energy nexus in the Algarve region. Finally, to decarbonize freshwater supply in the Algarve, policy instruments will need to account for unregulated pumping which enables conditions for groundwater depletion, encourage energy and water management integration, and explore innovative energy investments. • NAO (and EA) drive interannual variations with peak periods of 6.5 (and 3.5) -years. • Maximum energy demand in the water sector is expected for NAO+ and EA− phases. • SP is the most reliable renewable energy source for the water sector in the Algarve. • NAO+ EA− are associated with droughts raising implications for solar and wind energy. • Policies promoting solar based technologies should account for aquifer depletion. [ABSTRACT FROM AUTHOR]

Published

2021