Abstract
Background, aim, and scope
An innovative stabilization/solidification (S/S) process using high-performance additivated concrete technology was developed for remediating soil contaminated by metals from abandoned industrial sites. In order to verify the effectiveness of this new ex situ S/S procedure, an area highly contaminated by metallic pollutants (As, Cd, Hg, and Pb), due to the uncontrolled discharge of waste generated from artistic glass production on the island of Murano (Venice, Italy), was selected as a case study. The technique transforms the contaminated soil into an aggregate material suitable for reuse as on-site backfill. This paper reports the main results of the demonstration project performed in collaboration with the local environmental protection agency (ARPAV).
Materials and methods
An ex situ treatment for brownfield remediation, based on the transformation of contaminated soil into very dense, low porous, and mechanically resistant granular material, was set up and tested. Specific additives (water reducers and superplasticizers) to improve the stabilized material properties were developed and patented. A demonstration plant assembled on the study area to treat 6 m3 h–1was then tested. After excavation, the contaminated soil was screened to remove coarse material. The fraction Ø > 4 mm (coarse fraction), mainly composed of glass, brick, concrete, and stone debris, was directly reused on site after passing through a washing treatment section. The highly polluted fraction Ø ≤ 4 mm (fine fraction) was treated in the S/S treatment division of the plant (European patent WO/2006/097272). The fine fraction was mixed with Portland cement and additives defined on the basis of the high performance concrete technique. the mixture was then granulated in a rolling-plate system. After 28 days curing in an onsite storage area to allow for cement hydration, the stabilized material was monitored before its in situ relocation. The chemical, mechanical, and ecotoxicological reliability and performance of the treatment was checked. Metal leachability was verified according to four leaching test methods: Italian Environmental Ministry Decree (1998), EN 12457 (2002) tout court, amended only with MgSO4 and, lastly, with artificial sea water. The mechanical properties were measured according to BS (1990) and AASHTO (1999) to obtain the Aggregate Crushing Value and California Bearing Ratio, in that order. Moreover, leachate samples prepared with artificial seawater were assessed via the Crassostrea gigas embryotoxicity test and Vibrio fischeri bioluminescence inhibition test to discriminate the presence of potential ecotoxicological effects for the brackish and saltwater biota.
Results
Outcomes from all leachate samples highlighted the effectiveness of the remediation treatment, fully complying with the Italian legislation for non-hazardous material reuse under a physicochemical viewpoint. The stabilized granular material demonstrated high mechanical strength, low porosity, and leachability. Moreover, ecotoxicological surveys indicated the presence of low toxicity levels in leachate samples according to both toxicity tests.
Discussion
Remediated soil samples revealed a significant decrease in leachability of heavy metals as a consequence of the application of additivated cement that enhanced granular material properties, resulting in improved compactness due to the reduction in water content. The toxicity data confirmed this state-of-the-art technique, indicating that leachates could be deemed as minor acutely toxic.
Conclusions
The proposed S/S treatment proved to be able to remediate soil contaminated by heavy metals through trapping pollutants in pellet materials presenting adequate physicochemical, mechanical, and ecotoxicological properties in order to prevent leachability phenomena, their reclamation, and reuse being made easier by its granular form.
Recommendation and perspectives
This project foresees long-term monitoring activity over several years (until 2014) to consider treatment durability.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Explore related subjects
Discover the latest articles and news from researchers in related subjects, suggested using machine learning.References
AASHTO (1999) Standard Method of Test for the California Bearing Ratio. AASHTO, Washington, DC T 193
Al-Tabbaa A, Evans CW (1996) In-situ treatment of contaminated ground using soil mixing. Ground Eng 29:37
Al-Tabbaa A, Boes N (2002) Pilot in situ auger mixing treatment of a contaminated site. Part 4. Performance at 5 years. Proc Inst Civil Eng: Geotech Eng 155(3):187–202
APAT and IRSA-CNR (2003) Analytical methods for waters. APAT, Rome Report 29
APHA (1998) Standard methods for the examination of water and wastewater XX edition. APHA, Washington
ASTM (2004) Standard Guide for Conducting Static Acute Toxicity Tests Starting with Embryos of Four Species of Saltwater Bivalve Molluscs. E724–1998/2004
Azur Environmental (1998) Microtox acute toxicity test guide. Azur Environmental, Carlsbad Users manual
Board MJ, Reid JM, Fox DSJ, Grant DI (2000) The effects of age on cement stabilised/solidified contaminated material, TRL Report 451. Transport Research Laboratory, Crowthorne, UK
BS (British Standard) (1990) Testing aggregates. Methods for determination of aggregate crushing value (ACV). BS 812–110/112
Conner JR (1990) Chemical fixation and solidification of hazardous wastes. Nostrand Reinhold, New York
EMD (Environmental Ministry Decree) (1998) DLgs 5th February 1997. SOGU n. 88 16th April 1998
EMD (Environmental Ministry Decree) (1999) DLgs 471/1999. GU 293 15th December 1999
EN (2002) Characterization of waste—leaching—compliance test for leaching of granular waste materials and sludges—Part 4: one stage batch at a liquid to solid ratio of 10 l/kg for materials with particle size below 10 mm (without or with size reduction). (EN 12457–1–4)
EN (2007) Aggregates for unbound and hydraulically bound materials for use in civil engineering work and road construction (EN 13242:2002+A1)
EPA UK (2004) Review of scientific literature on the use of stabilisation/solidification for the treatment of contaminated soil, solid waste and sludges. EPA UK, London, Science Report SC980003/SR2
Felix F, Fraaij ALA, Hendriks CF (2000) Assessment of the Leaching due to Degradation Factors of Stabilised/Solidified Waste Materials. In: WASCON 2000 Fourth International Conference on the Environmental and Technical Implications of Construction with Alternative Materials. Harrogate, UK
FRTR (Federal Remediation Technologies Roundtable) (2008) Technical information on technologies for waste site cleanup, http://www.frtr.gov, 19th November 2008
Harbottle MJ, Al-Tabbaa A, Evans, CW (2007) A comparison of the technical sustainability of in situ stabilization/solidification with disposal to landfill. J Haz Mat 141:430–440
Libralato G, Losso C, Volpi Ghirardini A (2007) Toxicity of untreated wood leachates towards two saltwater organisms (Crassostrea gigas and Artemia franciscana). J Hazard Mater 144:590–593
Mulligan CN, Yong RN, Gibbs B (2001) Remediation technologies for metal-contaminated soils and groundwater: an evaluation. Eng Geol 60:193–207
Nawy EG (2000) Fundamentals of high-performance concrete. Wiley, Hoboken
Russell HG (1999) ACI defines high-performance concrete. Concr Intern 21:56–57
SedNet (2008) Urban Sediment Management and Port Redevelopment & Sediment in River Basin Management Plans - 5th International SedNet conference 27th-29th May 2008 Oslo, Norway
Surico F, Peli G, Zeno L, Scattolin M, Scanferla P, Rinaldo D (2003) The remediation of the Conterie in Murano (Venice). Battelle Press, Columbus Remediation of Contaminated Sediments. Proceedings of the Second International Conference on Remediation of Contaminated Sediments (Venice, 30th September–3rd October 2003)
Tandy S, Healey JR, Nason MA, Williamson JC, Davey LJ (2009) Remediation of metal polluted mine soil with compost: Co-composting versus incorporation. Env Poll 157(2):690–697
USEPA (1992) Methods for determination of metals in environmental sample. CRC, Boca Raton
USEPA (2000) Solidification/stabilization use at superfund sites. CRC, Boca Raton EPA 542-R-00-010
USEPA (2002) Chemical stabilization of mixed organic and metal compounds. CRC, Boca Raton EPA/600/J-92/403
Van-Camp L, Bujarrabal B, Gentile A-R, Jones RJA, Montanarella L, Olazabal C, Selvaradjou S-K (2004) Reports of the technical working groups established under the thematic strategy for soil protection. EUR 21319 EN/4, 872 pp. Office for Official Publications of the European Communities, Luxembourg
VROM (1999) Ministry of spatial planning, housing and environment. Building Material Decree
Wilke BM, Riepert F, Koch C, Kuhne T (2008) Ecotoxicological characterization of hazardous wastes. Ecotox Environ Saf 70:283–293
WIPO (Word Intellectual Property Organisation) (2006) WO/2006/097272. Lithoidal granular material Patent. WIPO, London International Application No. PCT/EP2006/002318
Acknowledgements
The authors are grateful to In.T.Ec. srl and Mapei spa for their technical and financial support, as well as to the Venice Municipality and Edilvenezia spa for logistics.
Author information
Authors and Affiliations
Corresponding author
Additional information
Responsible editor: Kay Hamer.
Rights and permissions
About this article
Cite this article
Scanferla, P., Ferrari, G., Pellay, R. et al. An innovative stabilization/solidification treatment For contaminated soil remediation: demonstration project results. J Soils Sediments 9, 229–236 (2009). https://doi.org/10.1007/s11368-009-0067-z
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11368-009-0067-z