Abstract
This study investigates soil erosion in a rapidly expanding industrial region of Eastern Mediterranean basin (Thriasio plain, Greece), controlling how geomorphology, topography, soil drainage and vegetation cover shape the local erosivity rate. Our results show that Thriasio plain is characterized by medium–low classes of soil vulnerability in the actual environmental conditions. However, in an ‘extreme conditions’ scenario, areas with sharp slope, a branched hydrographical network and low vegetation cover are classified at high vulnerability to soil erosion. A field study has been implemented considering extreme natural conditions (January 2004) driven by rapid snow melting determining an exceptionally high volume of water flooding down to the sea through a seasonal stream. This episode was considered a ‘natural experiment’ when assessing extreme soil erosion conditions. Based on theoretical calculations and field measurements, our results confirm the estimated value of soil erosion under the ‘extreme conditions’ scenario illustrated above.
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References
Abatzoglou G, Perdikouris D, Theologou E (1990) Quality of the ground waters on Thriasio Plain. Development Association of Thriasio Plain, Technical Report, Elefsis
Alexouli-Livaditi A, Livaditis G, Lykoudi E (2002) Investigation and delineation of areas of intense erosion and product of waste materials at Lesvos Island. In: Proceedings of the 6th Pan-Hellenic Geographical Congress, Thessaloniki (in Greek)
Christides A, Mavrakis A, Mitilineou A (2011) A case of intense seawater intrusion to aquifer of the Thriassio Plain, Greece. In: Proceeding of 12th international conference on environmental science and technology (12th ICEST), vol B, pp 152–159
Engel B (1999) Estimating soil erosion using RUSLE (revised universal soil loss equation) using Arcview. Purdue University (updated October 17, 2003)
Kaminari ΜΑ (1994) Geochemical pilot study of the soil in the Greater Elefsis area (Thriasio Plain) for the identification of pollution by trace metals. IGME, Technical Report, Athens
Karavitis CA, Bosdogianni A, Vlachos EC (2001) Environmental management approaches and water resources in the stressed region of Thriasio, Greece. Global Nest Int J 3(2):131–144
Kouni GD, Siemou ΝΕ (1991) Hydrogeological survey of the Thriassio Plain aquifers, for the water supply to the Hellenic Refineries of Aspropyrgos. IGME Technical Report, Athens
Koutsoyiannis D, Tarla Κ (1987) Sediment yield estimations in Greece. Tech Chron 3:A–7
Lykoudis S, Psounis N, Mavrakis A, Christides A (2008) Predicting photochemical pollution in an industrial area. Environ Monit Assess 142(1–3):279–288
Makri P, Kalivas D, Bathrellos G, Skilodimou H (2006) Spatio-temporal analysis of groundwater pollution from BTEX in Thriassio Field, Attica, Greece. In: IAEG2006 proceedings, paper 409
Mavrakis A, Theoharatos G, Asimakopoulos D, Christides A (2004) Distribution of the trace metals in sediments of Elefsis Gulf. Mediterr Mar Sci 5(1):151–158
Mavrakis A, Lykoudis S, Christides A, Dasaklis S, Tasopoulos A, Theoharatos G, Kyvelou S, Verouti E (2008) Air quality levels in a closed industrialized basin (Thriasio plain, Greece). Fresenius Environ Bull 17(4):443–454
Mavrakis A, Colantoni A, Salvati L (2014) Soil degradation, landscape and climate variations in a Mediterranean agro-forest system (Thriasio, Greece): proposal for a desertification indicator using time series analysis. Int J Agric Resour Gov Ecol 10(4):335–343
Mavrakis A, Papavasileiou C, Salvati L (2015) Towards (un)sustainable urban growth? Climate aridity, land-use changes and local communities in the industrial area of Thriasio plain. J Arid Environ 121:1–6
Papadopoulou MP, Karatzas GP, Koukadaki MA, Trichakis Y (2005) Modeling the saltwater intrusion phenomenon in coastal aquifers—a case study in the industrial zone of Herakleio in Crete. Global Nest Int J 7(2):197–203
Renard KG, Foster GR, Weesies GA, McCool DK, Yoder DC (1997) Predicting soil erosion by water: a guide to conservation planning with the Revised Universal Soil Loss Equation (RUSLE). Agriculture handbook no. 703. U.S. Department of Agriculture Research Service, Washington, District of Columbia, USA, 404
Saavedra C (2005) Estimating spatial patterns of soil erosion and deposition in the Andean region using geo-information techniques—A case study in Cochabamba, Bolivia. ITC & Wageningen University, Netherlands
Salvati L, Mavrakis A (2014) Narrative and quantitative analysis of human pressure, land–use and climate aridity in a transforming industrial basin in Greece. Int J Environ Res 8(1):115–122
Sigalos G, Alexouli-Livaditi A (2005) Investigation and delineation of areas of intense erosion and product of waste materials in the watershed of Sperchios river. In: Proceedings of the 1st scientific session of the geomorphology and environment commission of the Hellenic Geological Society, Athens (in Greek)
Stournaras G (1998) Groundwater and nitrates in Greece—an overview. J Environ Hydrol 6:1–8
Valmis S (1990) Erosion—conservation of soils. Agricultural University of Athens, Athens
Wischmeier WH, Johnson CB, Cross BW (1971) A soil erodibility nomograph for farmland and construction sites. J Soil Water Conserv 26(5):189–193
Zanchi C, Giordani C (1995) Elementi di conservazione del suolo. Pàtron Editore, Bologna
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Sigalos, G., Loukaidi, V., Dasaklis, S. et al. Soil erosion and degradation in a rapidly expanding industrial area of Eastern Mediterranean basin (Thriasio plain, Greece). Nat Hazards 82, 2187–2200 (2016). https://doi.org/10.1007/s11069-016-2288-y
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DOI: https://doi.org/10.1007/s11069-016-2288-y