nach oben

Environmental Earth Sciences

Erschienen in:

01.04.2018 | Original Article

Intrinsic groundwater vulnerability assessment: issues, comparison of different methodologies and correlation with nitrate concentrations in NW Italy

verfasst von: Manuela Lasagna, Domenico Antonio De Luca, Elisa Franchino

Erschienen in: Environmental Earth Sciences | Ausgabe 7/2018

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

The concept of aquifer vulnerability is certainly useful in the field of groundwater protection. Nevertheless, within the scientific community, the definition of vulnerability is still under debate and lacks standardisation. As a consequence, the methods for evaluating the vulnerability degree are numerous and often lead to conflicting results. Thus, in this study, three methods that are commonly used in groundwater vulnerability assessments due to their easy application (namely DRASTIC, GOD and TOT) were utilised in four areas of the Piedmont region (NW Italy). The results obtained by the different methods were compared and correlated with the nitrate concentrations in the groundwater. The aims of the study were (i) to evaluate the effectiveness of the adopted methods and their comparability, (ii) to discuss the limits of the intrinsic vulnerability methods and (iii) to verify the applicability of nitrate as a tracer in the assessment of groundwater vulnerability or explain the reasons why it is not applicable. It was observed that the three intrinsic vulnerability methods are not able to uniquely identify the most or least vulnerable areas. Additionally, the comparison of the intrinsic vulnerability indexes only occasionally showed a reasonable correlation. Furthermore, there was no clear correlation between the vulnerability indexes and nitrate concentrations in the groundwater. These results could be explained by several reasons: (1) the methods are mostly based on the level of groundwater protection provided by the overlaying lithologies and do not consider the physical processes occurring in the aquifer; (2) the intrinsic vulnerability methods only consider vertical pathways for contaminants, but a pre-existing contaminant could be present in the aquifer; (3) groundwater nitrate concentrations are affected by the nitrate input and surplus; and (4) nitrates are subject to physical and biological attenuation in aquifers and cannot necessarily be considered stable tracers in the assessment of groundwater vulnerability.

Vorheriger Artikel GIS-based landslide susceptibility evaluation using fuzzy-AHP multi-criteria decision-making techniques in the Abha Watershed, Saudi Arabia

Nächster Artikel Physical simulation research on evolution laws of clay aquifuge stability during slice mining

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Albinet M, Margat J (1970) Cartographie de la vulnérabilité à la pollution des nappes d’eau souterraine. Bull BRGM 2ème série 3(4):13–22

Aller L, Bennet T, Lehr JH, Petty RJ, Hackett G (1987) DRASTIC: a standardized system for evaluating ground-water pollution potential using hydrogeologic settings. NWWA/EPA Ser., EPA600/2-87-035, US Environmental Protection Agency, Ada, OK, USA

Antonakos AK, Lambrakis NJ (2007) Development and testing of three hybrid methods for the assessment of aquifer vulnerability to nitrates, based on the drastic model, an example from NE Korinthia, Greece. J Hydrol 333(2):288–304CrossRef

Aquater/Regione Piemonte (1988) Carta Litologico-giacimentologica. http://www.arpa.piemonte.it. Accessed 30 May 2017

ASTM (2002) Standard guide for selection of methods for assessing ground water or aquifer sensitivity and vulnerability. ASTM D6030-96, Philadelphia

Bekesi G, McConchie J (2002) The use of aquifer-media characteristics to model vulnerability to contamination, Manawatu region, New Zealand. Hydrogeol J 10:322–331CrossRef

Belmonte-Jiménez SI, Campos-Enríquez JO, Alatorre-Zamora MA (2005) Vulnerability to contamination of the Zaachila aquifer, Oaxaca, Mexico. Geofís Int 44(3):283–300

Bove A, Casaccio D, Destefanis E, De Luca DA, Lasagna M, Masciocco L, Ossella L, Tonussi M (2005) Assetto geoidrologico della Regione Piemonte. Idrogeologia della pianura piemontese, Regione Piemonte. Mariogros Industrie Grafiche S.p.A., Torino, p 17

Brouyère S, Jeannin PY, Dassargues A, Goldscheider N, Popescu IC, Sauter M, Vadillo I, Zwahlen F (2001) Evaluation and validation of vulnerability concepts using a physically based approach. In: Mudry J, Zwahlen F (eds) Proceedings of the 7th conference on limestone hydrology and fissured media. Sciences et Techniques de l’Environnement, Université de Franche-Comté, Mémoire n°13, pp 67–72

Bucci A, Barbero D, Lasagna M, Forno MG, De Luca DA (2017) Shallow groundwater temperature in the Turin area (NW Italy): vertical distribution and anthropogenic effects. Environ Earth Sci 76:221

Burigana E, Giupponi C, Bendoricchio G (2003) Nitrogen surplus as indicator of agricultural pollution impact in the Venice Lagoon Watershed. In: Bruen M (ed) Diffuse pollution and river basin management. Proceedings of the 7th IWA international conference, Dublin. IWA, pp 171–176

Castagna S, Dino GA, Lasagna M, De Luca DA (2015a) Environmental issues connected to the quarry lakes and chance to reuse fine materials deriving from aggregate treatments. In: Lollino G et al (eds) Engineering geology for society and territory – Volume 5, urban geology, sustainable planning and landscape exploitation. Springer, Switzerland, pp 71–74

Castagna SED, De Luca DA, Lasagna M (2015b) Eutrophication of Piedmont quarry lakes (north-western Italy): hydrogeological factors, evaluation of trophic levels and management strategies. J Env Assmt Pol Mgmt 17:4. https://doi.org/10.1142/S1464333215500362 (Codice Scopus: 2-s2.0-84949921862)

Civita M, De Regibus C (1995) Sperimentazione di alcune metodologie per la valutazione della vulnerabilità degli aquiferi (in Italian). Quaderni di Geologia Applicata, vol 3. Pitagora Ed, Bologna, pp 63–71

Corniello A, Ducci D, Napolitano P (1997) Comparison between parametric methods to evaluate aquifer pollution vulnerability using GIS: an example in the ‘‘Piana Campana’’, southern Italy. In: Marinos PG, Koukis GC, Tsiambaos GC, Stournaras GC (eds) Engineering geology and the environment. Balkema, Rotterdam, pp 1721–1726

Daly D, Dassargues A, Drew D, Dunne S, Goldscheider N, Neale S, Popescu C, Zwhalen F (2002) Main concepts of the “European Approach” for (karst) groundwater vulnerability assessment and mapping. Hydrogeol J 10(2):340–345CrossRef

De Luca DA (1990) Studio idrogeologico del settore Sud-Orientale della Pianura Torinese finalizzato alla valutazione della vulnerabilità e del rischio di inquinamento delle acque sotterranee. “Hydrogeological study of south-eastern Turin Plain aimed to vulnerability and groundwater pollution risk assessment”. Unpublished Ph.D. thesis, University of Torino, Italy

De Luca DA, Verga G (1991) Una metodologia per la valutazione della vulnerabilità degli acquiferi. Acque Sotter 29:30–33

De Luca DA, Destefanis E, Forno MG, Lasagna M, Masciocco L (2014) The genesis and the hydrogeological features of the Turin Po Plain fontanili, typical lowland springs in Northern Italy. Bull Eng Geol Environ 73:409–427

De Luca DA, Comina C, Lasagna M, Destefanis E, Masciocco L, Godio A, Stocco S (2018) Effectiveness of geophysical surveys for water wells relocation in overexploited aquifers (the example of Maggiore and Traversola Valleys, Northwestern Italy). Environ Earth Sci 77:19

Debernardi L, De Luca DA, Lasagna M (2008) Correlation between nitrate concentration in groundwater and parameters affecting aquifer intrinsic vulnerability. Environ Geol 55(3):539–558CrossRef

Dragoi IJ, Popa R (2007) Vulnerability assessment of a shallow aquifer situated in Danube’s plain (Olteniaregion, Romania) using different and overlay and index method. In: Witkowski AJ, Kowalczyk A, Vrba J (eds) Groundwater vulnerability assessment and mapping: selected papers from the Groundwater Vulnerability Assessment and Mapping International Conference: Ustron, Poland, 2004. Taylor & Francis, Balkema, pp 73–86

Evans TA, Maidment DR (1995) A spatial and statistical assessment of the vulnerability of Texas groundwater to nitrate contamination. CRWR Online Report 95-4. http://www.crwr.utexas.edu/gis/gishydro00/library/evans/rep95_4.htm

Foster SSD (1987) Fundamental concepts in aquifer vulnerability, pollution risk and protection strategy. In: Proceedings of the international conference on vulnerability of soil and groundwater to pollutants, Noordwijk, The Netherlands, pp 69–86

Foster S, Hirata R, Gomes D, D’Elia M, Paris M (2002) Groundwater quality protection: a guide for water utilities, municipal authorities and environment agencies. World Bank Publication, Washington, p 103CrossRef

Frind EO, Molson JW, Rudolph DL (2006) Well vulnerability: a quantitative approach for source water protection. Ground Water 44(5):732–742

Gillham RW, Cherry JA (1978) Field evidence of denitrification in shallow groundwater flow systems. Water Pollut Res Can 13(1):53–71

Grignani C, Sacco D (2005) Elaborazione dati e modellistica per l’individuazione delle zone vulnerabili da nitrati e da fitofarmaci e per la definizione e attuazione dei programmi d’azione. Final Report, p 14. (unpushed data)

Irace A, Clemente P, Natalicchio M, Ossella L, Trenkwalder S, De Luca DA, Mosca P, Piana F, Polino R, Violanti D (2009) Geologia e idrostratigrafia profonda della Pianura Padana occidentale. La Nuova Lito, Firenze

Javadi S, Kavehkar N, Mousavizadeh MH, Mohammadi K (2010) Modification of DRASTIC model to map groundwater vulnerability to pollution using nitrate measurements in agricultural areas. J Agric Sci Technol 13:239–249

Korom SF (1992) Natural denitrification in the saturated zone: a review. Water Resour Res 28:1657–1668CrossRef

Lasagna M, De Luca DA (2016) The use of multilevel sampling techniques for determining shallow aquifer nitrate profiles. Environ Sci Pollut Res 23:20431–20448CrossRef

Lasagna M, De Luca DA (2017) Evaluation of sources and fate of nitrates in the western Po Plain groundwater (Italy) using nitrogen and boron isotopes. Environ Sci Pollut Res. https://doi.org/10.1007/s11356-017-0792-6

Lasagna M, De Luca DA, Debernardi L, Clemente P (2013) Effect of the dilution process on the attenuation of contaminants in aquifers. Environ Earth Sci 70(6):2767–2784CrossRef

Lasagna M, Caviglia C, De Luca DA (2014) Simulation modeling for groundwater safety in an overexploitation situation: the Maggiore Valley context (Piedmont, Italy). Bull Eng Geol Environ 73:341–355. https://doi.org/10.1007/s10064-013-0500-9 (Codice ISI:000335156900007; Codice Scopus: 2-s2.0-84893203405)

Lasagna M, Franchino E, De Luca DA (2015) Areal and vertical distribution of nitrate concentration in Piedmont plain aquifers (North-western Italy). In: Lollino G et al (eds) Engineering geology for society and territory—volume 3, river basins, reservoir sedimentation and water resources. Springer, Basel, pp 389–392

Lasagna M, De Luca DA, Franchino E (2016a) The role of physical and biological processes in aquifers and their importance on groundwater vulnerability to nitrate pollution. Environ Earth Sci 75:961. https://doi.org/10.1007/s12665-016-5768-1 CrossRef

Lasagna M, De Luca DA, Franchino E (2016b) Nitrate contamination of groundwater in the western Po Plain (Italy): the effects of groundwater and surface water interactions. Environ Earth Sci 75:240. https://doi.org/10.1007/s12665-015-5039-6 CrossRef

Martinelli G, Dadomo A, De Luca DA, Mazzola M, Lasagna M, Pennisi M, Pilla G, Sacchi E, Saccon P (2018) Nitrate sources, accumulation and reduction in groundwater from Northern Italy: insights provided by a nitrate and boron isotopic database. Appl Geochem 91C(2018):23–35CrossRef

Masetti M, Poli S, Sterlacchini S, Beretta GP, Facchi A (2008) Spatial and statistical assessment of factors influencing nitrate contamination in groundwater. J Environ Manag 86(1):272–281CrossRef

NRC (1993) Groundwater vulnerability assessment, contamination potential under condition of uncertainty. National Academy Press, Washington, DC

Panagopoulos GP, Antonakos AK, Lambrakis NJ (2006) Optimization of the DRASTIC method for groundwater vulnerability assessment via the use of simple statistical methods and GIS. Hydrogeol J 14(6):894–911CrossRef

Postma D, Boesen C, Kristiansen H, Larsen F (1991) Nitrate reduction in an unconfined aquifer: water chemistry, reduction processes, and geochemical modeling. Water Resour Res 27:2027–2045CrossRef

Regione Piemonte (2007) Piano di tutela delle acque. http://www.regione.piemonte.it/ambiente/acqua/pianoTAcque.htm. Accessed 20 Sept 2017

Regione Piemonte (2010) Carta dei suoli 1:50000. http://www.regione.piemonte.it/agri/area_tecnico_scientifica/suoli/suoli1_50/cartografia.htm. Accessed 20 Sept 2017

Sànchez-Pérez JM, Bouey C, Sauvage S, Teissier S, Antiguedad I, Vervier P (2003) A standardised method for measuring in situ denitrification in shallow aquifers: numerical validation and measurements in riparian wetlands. Hydrol Earth Syst Sci 7(1):87–96CrossRef

Sener E, Sener S, Davraz A (2009) Assessment of aquifer vulnerability based on GIS and DRASTIC methods: a case study of the Senirkent–Uluborlu Basin (Isparta, Turkey). Hydrogeol J 17(8):2023–2035CrossRef

Sorichetta A (2010) Groundwater vulnerability assessment using statistical methods. PhD thesis. Scuola di Dottorato in Terra, Ambiente e Biodiversita. Università degli Studi di Milano

Starr RC, Gillham RW (1993) Denitrification and organic carbon availability in two aquifers. Ground Water 31(6):934–947CrossRef

Stevenazzi S, Masetti M, Beretta GP (2017) Groundwater vulnerability assessment: from overlay methods to statistical methods in the Lombardy Plain area. Acque Sotter Ital J Groundw AS21–276:17–27

Stigter TY, Ribeiro L, Carvalho Dill AMM (2006) Evaluation of an intrinsic and a specific vulnerability assessment method in comparison with groundwater salinisation and nitrate contamination levels in two agricultural regions in the south of Portugal. Hydrogeol J 14:79–99CrossRef

Stigter TY, Carvalho Dill AMM, Ribeiro L (2011) Major issues regarding the efficiency of monitoring programs for nitrate contaminated groundwater. Environ Sci Technol 45(20):8674–8682CrossRef

Toda H, Mochizuki Y, Kawanishi T, Kawashima H (2002) Denitrification in shallow groundwater in a coastal agricultural area in Japan. Nutr Cycl Agroecosyst 63:167–173CrossRef

US Environment Protection Agency (1996) Drinking water regulations and health advisories. US Environmental Protection Agency Report 822-B-96-002. Office of Water, Washington, DC

Vrba J, Zaporozec A (1994) Guidebook on mapping groundwater vulnerability. International association of hydrogeologists, international contributions to hydrogeology, vol 16. Verlag Heinz Heise, Hannover

Wachniew P, Zurek AJ, Stumpp C, Gemitzi A, Gargini A, Filippini M, Rozanski K, Meeks J, Kværner J, Witczak S (2016) Toward operational methods for the assessment of intrinsic groundwater vulnerability: a review. Crit Rev Environ Sci Technol 46(9):827–884CrossRef

Yu C, Yao Y, Hayes G, Zhang B, Zheng C (2010) Quantitative assessment of groundwater vulnerability using index system and transport simulation, Huangshuihe catchment, China. Sci Total Environ 408(24):6108–6116CrossRef

Zampetti M (1983) Informazioni e dati relativi alla quantità ed alla qualità delle acque sotterranee nella Comunità Europea. In: Proceedings of the International Conference “Inquinamento delle Acque sotterranee da composti organo-clorurati di origine industriale”. Milano, pp 197–204

Titel: Intrinsic groundwater vulnerability assessment: issues, comparison of different methodologies and correlation with nitrate concentrations in NW Italy
verfasst von: Manuela Lasagna
Domenico Antonio De Luca
Elisa Franchino
Publikationsdatum: 01.04.2018
Verlag: Springer Berlin Heidelberg
Erschienen in: Environmental Earth Sciences / Ausgabe 7/2018
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI: https://doi.org/10.1007/s12665-018-7452-0

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Weitere Artikel der Ausgabe 7/2018

Evaluation of heavy metal contamination in roadside deposited sediments and road surface runoff: a case study

Assessment of radiation exposure to human and non-human biota due to natural radionuclides in terrestrial environment of Belgrade, the capital of Serbia

A numerical model in predicting the initial karst development in porous limestone

Long-term seasonal rainfall forecasting: efficiency of linear modelling technique

Human health risk assessment of groundwater nitrogen pollution in Jinghui canal irrigation area of the loess region, northwest China

Groundwater chemical indices changed due to water-level decline, Minab Plain, Iran