Your search keyword '"Anna Malagó"' showing total 8 results

1. River and lake nutrient targets that support ecological status: European scale gap analysis and strategies for the implementation of the Water Framework Directive

Author

Anna Malagó, Fayçal Bouraoui, Geoff Phillips, Sandra Poikane, Gábor Várbíró, Maria Α. Lilli, and Nikolaos P. Nikolaidis

Subjects

China, Environmental Engineering, Nitrogen, chemistry.chemical_element, European waters, Structural basin, Ecosystem services, Gap analysis, Nutrient, Rivers, Environmental Chemistry, Waste Management and Disposal, Ecosystem, Ecology, business.industry, Phosphorus, Ecological status, Water, Nutrients, Eutrophication, Pollution, Lakes, chemistry, Water Framework Directive, Agriculture, Nutrient targets, Environmental science, business, Surface water, Water Pollutants, Chemical, Environmental Monitoring

Abstract

Eutrophication caused by an excessive presence of nutrients is affecting large portions of European waters with more than 60% of the surface water bodies failing to achieve the primary ambition of water management in Europe, that of good ecological status (GES) with diffuse emission from agriculture being the second most important pressure affecting surface waters. We developed EU wide and regional nutrient targets that define the boundary concentrations between good and moderate status for river and lake total P (TP) and total N (TN) and assessed the gap between actual nutrient concentrations and these targets and considered strategies of nutrient reductions necessary to achieve GES and deliver ecosystem services. The nutrient targets established for rivers ranged from 0.5–3.5 mg/L TN and 11–105 μg/L TP and for lakes 0.5–1.8 mg/L TN and 10–60 μg/L TP. Based on the EU wide targets, 59% of the TN and 57% of the TP river monitoring sites and 64% of the TN and 61% of the TP lake monitoring sites exceed these value and are thus at less than GES. The PCA and step-wise regression for EU basins clearly showed that the basin nutrient export is predominantly related to agricultural inputs. In addition, the step-wise regression models for TN and TP provided the ability to extrapolate the results and quantify the input reductions necessary for reaching the nutrient targets at the EU level. The results suggest that a dual water management strategy would be beneficial and should focus a) on those less polluted rivers and lakes that can easily attain the GES goal and b) on the more highly polluted systems that will improve the delivery of ecosystem services.

Published

2022

2. Regulations on Nitrate Use and Management

Author

Fayçal Bouraoui, Panos Panagos, Anna Malagó, Alberto Pistocchi, and Christophe Didion

Subjects

chemistry.chemical_compound, Nitrate, chemistry, Environmental engineering, Environmental science

Published

2021

3. Modelling water and nutrient fluxes in the Danube River Basin with SWAT

Author

Fayçal Bouraoui, Marco Pastori, Olga Vigiak, Bruna Grizzetti, and Anna Malagó

Subjects

Nitrogen and phosphorus balances, Environmental Engineering, 010504 meteorology & atmospheric sciences, Drainage basin, Streamflow, Review, 010501 environmental sciences, Structural basin, 01 natural sciences, Environmental Chemistry, SWAT model, Danube, Waste Management and Disposal, 0105 earth and related environmental sciences, Riparian zone, Hydrology, geography, Baseflow, geography.geographical_feature_category, Pollution, Nutrient concentrations, Environmental science, Swat, Water quality, Surface runoff

Abstract

This study provides an innovative process-based modelling approach using the SWAT model and shows its application to support the implementation of the European environmental policies in large river basins. The approach involves several pioneering modelling aspects: the inclusion of current management practices; an innovative calibration and validation methodology of streamflow and water quality; a sequential calibration starting from crop yields, followed by streamflow and nutrients; and the use of concentrations instead of loads in the calibration. The approach was applied in the Danube River Basin (800,000 km2), the second largest river basin in Europe, that is under great nutrients pressure. The model was successfully calibrated and validated at multiple gauged stations for the period 1995–2009. About 70% and 61% of monthly streamflow stations reached satisfactory performances in the calibration and validation datasets respectively. N-NO3 monthly concentrations were in good agreement with the observations, albeit SWAT could not represent accurately the spatial variability of the denitrification process. TN and TP concentrations were also well captured. Yet, local discrepancies were detected across the Basin. Baseflow and surface runoff were the main pathways of water pollution. The main sinks of TN and TP diffuse emissions were plant uptake which captured 58% of TN and 92% of TP sources, then soil retention (35% of TN and 2% of TP), riparian filter strips (2% both for TN and TP) and river retention (2% of TN and 4% of TP). Nitrates in the aquifer were estimated to be around 3% of TN sources. New reliable “state-of-the-art” knowledge of water and nutrients fluxes in the Danube Basin were thus provided to be used for assessing the impact of best management practices and for providing support to the implementation of the European Environmental Directives., Graphical abstract Image 2, Highlights • A new SWAT model's calibration and validation method for water quantity and quality is provided. • The approach includes prediction of concentrations as affected by current conservation measures. • Modelled water and nutrient balances can guide conservation management. • Prediction of nutrient concentrations increased the robustness of nutrient fluxes estimations.

Published

2017

4. Uncertainty of modelled flow regime for flow-ecological assessment in Southern Europe

Author

Angeliki Mentzafou, Ralf Merz, Alberto Pistocchi, Fayçal Bouraoui, Nikolaos Skoulikidis, Ad de Roo, Stefanie Lutz, Rohini Kumar, Ralf Ludwig, Gabriele Chiogna, Alberto Bellin, C. Gamvroudis, Bruno Majone, Luis Samaniego, Olga Vigiak, Nikolaos P. Nikolaidis, Vicenç Acuňa, Hylke E. Beck, Ye Tuo, Anna Malagó, and Nataša Mori

Subjects

Environmental Engineering, Ecohydrological assessment, 0208 environmental biotechnology, Flow (psychology), Drainage basin, 02 engineering and technology, Structural basin, Streamflow, Lisflood, Environmental Chemistry, SWAT, Uncertainty quantification, Drainage, HYPERstream, Waste Management and Disposal, Hydrology, geography, geography.geographical_feature_category, Flow regime, mHM, Pollution, Ecological assessment, 6. Clean water, 020801 environmental engineering, ddc, Current (stream), 13. Climate action, Environmental science

Abstract

Summarization: Sustainable water basin management requires characterization of flow regime in river networks impacted by anthropogenic pressures. Flow regime in ungauged catchments under current, future, or natural conditions can be assessed with hydrological models. Developing hydrological models is, however, resource demanding such that decision makers might revert to models that have been developed for other purposes and are made available to them (‘off-the-shelf’ models). In this study, the impact of epistemic uncertainty of flow regime indicators on flow-ecological assessment was assessed at selected stations with drainage areas ranging from about 400 to almost 90,000 km 2 in four South European basins (Adige, Ebro, Evrotas and Sava). For each basin, at least two models were employed. Models differed in structure, data input, spatio-temporal resolution, and calibration strategy, reflecting the variety of conditions and purposes for which they were initially developed. The uncertainty of modelled flow regime was assessed by comparing the modelled hydrologic indicators of magnitude, timing, duration, frequency and rate of change to those obtained from observed flow. The results showed that modelled flow magnitude indicators at medium and high flows were generally reliable, whereas indicators for flow timing, duration, and rate of change were affected by large uncertainties, with correlation coefficients mostly below 0.50. These findings mirror uncertainty in flow regime indicators assessed with other methods, including from measured streamflow. The large indicator uncertainty may significantly affect assessment of ecological status in freshwater systems, particularly in ungauged catchments. Finally, flow-ecological assessments proved very sensitive to reference flow regime (i.e., without anthropogenic pressures). Model simulations could not adequately capture flow regime in the reference sites comprised in this study. The lack of reliable reference conditions may seriously hamper flow-ecological assessments. This study shows the pressing need for improving assessment of natural flow regime at pan-European scale. Presented on

Published

2018

5. Modelling sediment fluxes in the Danube River Basin with SWAT

Author

Fayçal Bouraoui, Samo Grošelj, Olga Vigiak, Florin Obreja, Helmut Habersack, Matthias Vanmaercke, Anna Malagó, Jean Poesen, and János Fehér

Subjects

Hydrology, geography, Environmental Engineering, geography.geographical_feature_category, 0208 environmental biotechnology, Drainage basin, Sediment, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Pollution, Deposition (geology), 020801 environmental engineering, Tributary, Erosion, Environmental Chemistry, Environmental science, SWAT model, Waste Management and Disposal, Sedimentary budget, Stream power, 0105 earth and related environmental sciences

Abstract

Sediment management is of prior concern in the Danube Basin for provision of economic and environmental services. This study aimed at assessing current (1995-2009) sediment fluxes of the Danube Basin with SWAT model and identifying sediment budget knowledge gaps. After hydrologic calibration, hillslope gross erosion and sediment yields were broadly calibrated using ancillary data (measurements in plots and small catchments, and national and European erosion maps). Mean annual sediment concentrations (SSC) from 269 gauging stations (2968 station-year entries; median 19mg/L, interquartile range IQR 10-36mg/L) were used for calibrating in-stream sediments. SSC residuals (simulations-observations) median was 2mg/L (IQR -14; +22mg/L). In the validation dataset (172 gauging stations; 1457 data-entries, median 17mg/L, IQR 10-28), median residual was 9mg/L (IQR -9; +39mg/L). Percent bias in an independent dataset of annual sediment yields (SSY; 689 data-entries in 95 stations; median 52t/km2/y, IQR 20-151t/km2/y) was -21.5%. Overall, basin-wide model performance was considered satisfactory. Sediment fluxes appeared overestimated in some regions (Sava and Velika Morava), and underestimated in others (Siret-Prut and Romanian Danube), but unbiased elsewhere. According to the model, most sediments were generated by hillslope erosion. Streambank degradation contributed about 5% of sediments, and appeared important in high stream power Alpine reaches. Sediment trapping in reservoirs and floodplain deposition was probably underestimated and counterbalanced by high stream deposition. Factor analysis showed that model underestimations were correlated to Alpine and karst areas, whereas underestimations occurred in high seismicity areas of the Lower Danube. Contemporary sediment fluxes were about one third of values reported for the 1980s for several tributaries of the Middle and Lower Danube. Knowledge gaps affecting the sediment budget were identified in the contributions of some erosion processes (glacier erosion, gully erosion and mass movements), and in-stream sediment dynamics. publisher: Elsevier articletitle: Modelling sediment fluxes in the Danube River Basin with SWAT journaltitle: Science of The Total Environment articlelink: http://dx.doi.org/10.1016/j.scitotenv.2017.04.236 content_type: article copyright: © 2017 The Authors. Published by Elsevier B.V. ispartof: Science of the Total Environment vol:599 pages:992-1012 ispartof: location:Netherlands status: published

Published

2017

6. Identifying Efficient Nitrate Reduction Strategies in the Upper Danube

Author

Marco Pastori, Olga Vigiak, Fayçal Bouraoui, Anna Malagó, Arnaud Reynaud, Francisco Javier Elorza, Angel Udias, Dokuchaev Soil Science Institute (SSI), Russian Academy of Agricultural Sciences, Toulouse School of Economics (TSE), École des hautes études en sciences sociales (EHESS)-Institut National de la Recherche Agronomique (INRA)-Centre National de la Recherche Scientifique (CNRS)-Université Toulouse 1 Capitole (UT1), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées, and Universidad Politécnica de Madrid (UPM)

Subjects

Pollution, lcsh:Hydraulic engineering, Best Management Practices (BMP), SWAT, multi-objective optimization, point and diffuse sources pollution, nutrients reduction, media_common.quotation_subject, 0208 environmental biotechnology, Geography, Planning and Development, 02 engineering and technology, Aquatic Science, Structural basin, Biochemistry, Multi-objective optimization, [SHS]Humanities and Social Sciences, 12. Responsible consumption, chemistry.chemical_compound, lcsh:Water supply for domestic and industrial purposes, best management practices, Nitrate, lcsh:TC1-978, 11. Sustainability, B- ECONOMIE ET FINANCE, Nonpoint source pollution, Water Science and Technology, media_common, lcsh:TD201-500, business.industry, Environmental engineering, 15. Life on land, 6. Clean water, 020801 environmental engineering, Current (stream), chemistry, 13. Climate action, Agriculture, Environmental science, Sewage treatment, business

Abstract

International audience; Nitrogen losses in the form of Nitrate (N-NO3) from point and diffuse sources of pollution are recognized to be the leading cause of water body impairment throughout Europe. Implementation of conservation programs is perceived as being crucial for restoring and protecting the good ecological status of freshwater bodies. The success of conservation programs depends on the efficient identification of management solutions with respect to the envisaged environmental and economic objectives. This is a complex task, especially considering that costs and effectiveness of conservation strategies depend on their locations. We applied a multi-objective, spatially explicit analysis tool, the R-SWAT-DM framework, to search for efficient, spatially-targeted solution of Nitrate abatement in the Upper Danube Basin. The Soil Water Assessment Tool (SWAT) model served as the nonpoint source pollution estimator for current conditions as well as for scenarios with modified agricultural practices and waste water treatment upgrading. A spatially explicit optimization analysis that considered point and diffuse sources of Nitrate was performed to search for strategies that could achieve largest pollution abatement at minimum cost. The set of optimal spatial conservation strategies identified in the Basin indicated that it could be possible to reduce Nitrate loads by more than 50% while simultaneously provide a higher income.

Published

2016

7. Adapting SWAT hillslope erosion model to predict sediment concentrations and yields in large Basins

Author

Matthias Vanmaercke, Anna Malagó, Olga Vigiak, Fayçal Bouraoui, and Jean Poesen

Subjects

Geologic Sediments, Geological Phenomena, Environmental Engineering, Soil and Water Assessment Tool, Drainage basin, Multi-site calibration, Structural basin, Sediment budget, Upper Danube, Environmental Chemistry, SWAT, Sedimentary budget, Waste Management and Disposal, Hydrology, geography, geography.geographical_feature_category, Water Pollution, Sediment, MUSLE, Models, Theoretical, Pollution, Universal Soil Loss Equation, Erosion, Environmental science, Water erosion, Sediment load, Sediment transport, Environmental Monitoring

Abstract

The Soil and Water Assessment Tool (SWAT) is used worldwide for water quality assessment and planning. This paper aimed to assess and adapt SWAT hillslope sediment yield model (Modified Universal Soil Loss Equation, MUSLE) for applications in large basins, i.e. when spatial data is coarse and model units are large; and to develop a robust sediment calibration method for large regions. The Upper Danube Basin (132,000km(2)) was used as case study representative of large European Basins. The MUSLE was modified to reduce sensitivity of sediment yields to the Hydrologic Response Unit (HRU) size, and to identify appropriate algorithms for estimating hillslope length (L) and slope-length factor (LS). HRUs gross erosion was broadly calibrated against plot data and soil erosion map estimates. Next, mean annual SWAT suspended sediment concentrations (SSC, mg/L) were calibrated and validated against SSC data at 55 gauging stations (622 station-years). SWAT annual specific sediment yields in subbasin reaches (RSSY, t/km(2)/year) were compared to yields measured at 33 gauging stations (87station-years). The best SWAT configuration combined a MUSLE equation modified by the introduction of a threshold area of 0.01km(2) where L and LS were estimated with flow accumulation algorithms. For this configuration, the SSC residual interquartile was less than +/-15mg/L both for the calibration (1995-2004) and the validation (2005-2009) periods. The mean SSC percent bias for 1995-2009 was 24%. RSSY residual interquartile was within +/-10t/km(2)/year, with a mean RSSY percent bias of 12%. Residuals showed no bias with respect to drainage area, slope, or spatial distribution. The use of multiple data types at multiple sites enabled robust simulation of sediment concentrations and yields of the region. The MUSLE modifications are recommended for use in large basins. Based on SWAT simulations, we present a sediment budget for the Upper Danube Basin. publisher: Elsevier articletitle: Adapting SWAT hillslope erosion model to predict sediment concentrations and yields in large Basins journaltitle: Science of The Total Environment articlelink: http://dx.doi.org/10.1016/j.scitotenv.2015.08.095 content_type: article copyright: Copyright © 2015 Published by Elsevier B.V. ispartof: Science of the Total Environment vol:538 pages:855-875 ispartof: location:Netherlands status: published

Published

2015

8. Identifying efficient agricultural irrigation strategies in Crete

Author

Fayçal Bouraoui, A. Udias, Olga Vigiak, Anna Malagó, Marco Pastori, and Nikolaos P. Nikolaidis

Subjects

Irrigation, Environmental Engineering, Watershed, Soil and Water Assessment Tool, Water scarcity, business.industry, 0208 environmental biotechnology, Best Management Practices, 02 engineering and technology, Pollution, 020801 environmental engineering, Multi-objective optimization, R-SWAT-DM, Agriculture, Sustainability, Environmental Chemistry, Environmental science, Irrigation management, Water resource management, business, Waste Management and Disposal, Water use

Abstract

Summarization: Water scarcity and droughts are a major concern in most Mediterranean countries. Agriculture is a major user of water in the region and releases significant amounts of surface and ground waters, endangering the sustainable use of the available resources. Best Management Practices (BMPs) can mitigate the agriculture impacts on quantity of surface waters in agricultural catchments. However, identification of efficient BMPs strategies is a complex task, because BMPs costs and effectiveness can vary significantly within a basin. In this study, sustainable agricultural practices were studied based on optimal allocation of irrigation water use for dominant irrigated crops in the island of Crete, Greece. A decision support tool that integrates the Soil and Water Assessment Tool (SWAT) watershed model, an economic model, and multi-objective optimization routines, was used to identify and locate optimal irrigation strategies by considering crop water requirements, impact of irrigation changes on crop productivity, management strategies costs, and crop market prices. Three spatial scales (crop type, fields, and administrative regions) were considered to point out different approaches of efficient management. According to the analysis, depending on the spatial scale and complexity of spatial optimization, water irrigation volumes could be reduced by 32%–70% while preserving current agricultural benefit. Specific management strategies also looked at ways to relocate water between administrative regions (4 prefectures in the case of Crete) to optimize crop benefit while reducing global water use. It was estimated that an optimal reallocation of water could reduce irrigation water volumes by 52% (148 Mm3/y) at the cost of a 7% (48 M€) loss of agricultural income, but maintaining the current agricultural benefit (626.9 M€). The study showed how the identification of optimal, cost-effective irrigation management strategies can potentially address the water scarcity issue that is becoming crucial for the viability of agriculture in the Mediterranean region. Presented on: Science of the Total Environment