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ORGANIC RICH FRESHWATER SEDIMENTS (SAPROPEL) AS POTENTIAL SOIL AMENDMENT FOR RECULTIVATION OF AREAS CONTAMINATED WITH HEAVY METALS
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References44
Korde, N.V. Biostratification and typology of Russian sapropels. Moscow, Publisher of the USSR Academy of Science, 1960, pp 280.
Salomons, W. Biogeodynamics of contaminated sediments and soils: Perspectives for future research. Journal of Geochemical Exploration, vol. 62, pp 37-40, 1998.
Stankevica K., Klavins M., Rutina L. Accumulation of Metals in Sapropel. Material Science and Applied Chemistry, vol. 26, pp. 99-105, 2012.
Directive 2008/1/EC of the European Parliament and of the Council of 15 January 2008 concerning integrated pollution prevention and control. Text with EEA relevance. Official Journal of the European Union, L 24/8.
Lado L.R., Hengl T., Reuter H.I. Heavy metals in European soils: a geostatistical analysis of the FOREGS Geochemical database. Geoderma 148, pp 189–199, 2008.
Lee S.M., Laldawngliana C., Tiwari D. Iron oxide nano-particles-immobilized-sand material in the treatment of Cu(II), Cd(II) and Pb(II) contaminated waste waters. Chem Eng J., vol. 195–196, pp 103–111, 2012.
Yadav S., Srivastava V., Banerjee S., Gode F. , Sharma Y.C. (2012) Studies on the removal of nickel from aqueous solutions using modified riverbed sand. Environ Sci Pollut Res, vol. 20/issue 1, pp 558-567, 2012.
Byrne L.A., Hynes M.J., Connolly C.D., Murphy R.A. Analytical determination of apparent stability constants using a copper ion selective electrode. Journal of Inorganic BiochemistryI, vol. 105/issue 12, pp 1656-1661, 2011.
Cremers, A., Elsen, A., De Preter, P. & Maes, A., 1988. Quantitative analysis of ra diocaesium retention in soils. Nature, vol. 335, pp 247-249, 1988. Section Soils
Moskalchuk L.N. Using Sapropels as Adsorbents for Reclaiming Radionuclide Contaminated Soils. Proceedings of the National Academy of Sciences of Belarus. Chemical Series, vol. 4, pp 86-91, 2005.
Kapustina I.B., Maskalchuk L.N., Matushonok T.G., Pozylova N.M., Khololovich M.E. Research on hydrolyzed lignin for possible using as amendments for rehabilitation of soils contaminated by radionuclides. Chemistry for sustainable development , vol. 1, pp 17– 22, 2006.
Maskalchuk L.N. Development of new agents and methods for immobilization of radionuclides and technologies of their safe disposal in Belarus. Collaboration in the area of decommissioning of nuclear facilities and radioactive waste. Proceedings of the international conference on strategic, technical and practical experiences in Central Eastern Europe and Russia, Lithuania, pp 365-374, 2007.
Konoplev A.V., Bulgakov A.A., Moskalchuk L.N., Popov V.E. Development of amendments for rehabilitation of soils, contaminated by radionuclides and assessment of their application efficacy. Proceeding of International Conference on Radioecology and Environmental Radioactivity, Norway, 2008.
Braks, N. A. Sapropel sediments and application possibilities . Publishing Hause „Zinatne”, 1971, pp 60.
Geological Expedition Materials on Sapropel and Peat Research. Geological Prospecting Expedition , Man. and Ed.: Alksnitis R. Riga, State Geological Survey, 1990-1991, 1997, 2000 (unpublished).
Konoplev A., Maskalchuk L. Development of Composition and Technology of Additives Production for Rehabilitation of Soils Contaminated by Radionuclides and Assessment of their Application Efficiency, Tokyo, 2012.
Regulation of the Cabinet of Ministers Nr.483. Identification and Registration of Contaminated and Potentially Conta minated Sites (in Latvian: Piesārņoto un potenciāli piesārņoto vietu apzināšanas un reģistrācijas kārtība) ("LV", 171 (2558), 27.11.2001.) [in power from 28.11.2001.]; with Amendments.
National Register of Contaminated and Potentially Contaminated Sites (in Latvian: Piesārņoto un potenciāli piesārņoto vietu reģistrs). LVĢMC. Accessed: 07.04.2011. Available: http://oas.vdc.lv:7779/p_ppv.html
Burlakovs J., Klavins M. Stabilization and Solidification Technology Implementation in Latvia: First Studies. International Journal of Environmental Pollution and Remediation, vol. 1/issue 1, 2012.
Burlakovs J. and Vircavs M. Heavy Metal Remediation Technologies in Latvia: Possible Applications and Preliminary Case Study Results. Ecological Chemistry and Engineering, vol. 19/issue 4, pp 533-547, 2012.
National Register of Contaminated and Potentially Contaminated Sites (in Latvian: Piesārņoto un potenciāli piesārņoto vietu reģistrs). LVĢMC. Accessed: 07.04.2013. Available: http://oas.vdc.lv:7779/p_ppv.html
Burlakovs J., Vircavs M. (2011). Possible Applications of Soil Remediation Technologies in Latvia, Scientific Journal of Riga Technical University, vol. 7/issue 1, pp 46-53, 2012. GeoConference on Water Resources. Forest, Marine and Ocean Ecosystems
Korde, N.V. Biostratification and typology of Russian sapropels. Moscow, Publisher of the USSR Academy of Science, 1960, pp 280.
Salomons, W. Biogeodynamics of contaminated sediments and soils: Perspectives for future research. Journal of Geochemical Exploration, vol. 62, pp 37-40, 1998.
Stankevica K., Klavins M., Rutina L. Accumulation of Metals in Sapropel. Material Science and Applied Chemistry, vol. 26, pp. 99-105, 2012.
Directive 2008/1/EC of the European Parliament and of the Council of 15 January 2008 concerning integrated pollution prevention and control. Text with EEA relevance. Official Journal of the European Union, L 24/8.
Lado L.R., Hengl T., Reuter H.I. Heavy metals in European soils: a geostatistical analysis of the FOREGS Geochemical database. Geoderma 148, pp 189–199, 2008.
Lee S.M., Laldawngliana C., Tiwari D. Iron oxide nano-particles-immobilized-sand material in the treatment of Cu(II), Cd(II) and Pb(II) contaminated waste waters. Chem Eng J., vol. 195–196, pp 103–111, 2012.
Yadav S., Srivastava V., Banerjee S., Gode F. , Sharma Y.C. (2012) Studies on the removal of nickel from aqueous solutions using modified riverbed sand. Environ Sci Pollut Res, vol. 20/issue 1, pp 558-567, 2012.
Byrne L.A., Hynes M.J., Connolly C.D., Murphy R.A. Analytical determination of apparent stability constants using a copper ion selective electrode. Journal of Inorganic BiochemistryI, vol. 105/issue 12, pp 1656-1661, 2011.
Cremers, A., Elsen, A., De Preter, P. & Maes, A., 1988. Quantitative analysis of ra diocaesium retention in soils. Nature, vol. 335, pp 247-249, 1988. Section Soils
Moskalchuk L.N. Using Sapropels as Adsorbents for Reclaiming Radionuclide Contaminated Soils. Proceedings of the National Academy of Sciences of Belarus. Chemical Series, vol. 4, pp 86-91, 2005.
Kapustina I.B., Maskalchuk L.N., Matushonok T.G., Pozylova N.M., Khololovich M.E. Research on hydrolyzed lignin for possible using as amendments for rehabilitation of soils contaminated by radionuclides. Chemistry for sustainable development , vol. 1, pp 17– 22, 2006.
Maskalchuk L.N. Development of new agents and methods for immobilization of radionuclides and technologies of their safe disposal in Belarus. Collaboration in the area of decommissioning of nuclear facilities and radioactive waste. Proceedings of the international conference on strategic, technical and practical experiences in Central Eastern Europe and Russia, Lithuania, pp 365-374, 2007.
Konoplev A.V., Bulgakov A.A., Moskalchuk L.N., Popov V.E. Development of amendments for rehabilitation of soils, contaminated by radionuclides and assessment of their application efficacy. Proceeding of International Conference on Radioecology and Environmental Radioactivity, Norway, 2008.
Braks, N. A. Sapropel sediments and application possibilities . Publishing Hause „Zinatne”, 1971, pp 60.
Geological Expedition Materials on Sapropel and Peat Research. Geological Prospecting Expedition , Man. and Ed.: Alksnitis R. Riga, State Geological Survey, 1990-1991, 1997, 2000 (unpublished).
Konoplev A., Maskalchuk L. Development of Composition and Technology of Additives Production for Rehabilitation of Soils Contaminated by Radionuclides and Assessment of their Application Efficiency, Tokyo, 2012.
Regulation of the Cabinet of Ministers Nr.483. Identification and Registration of Contaminated and Potentially Conta minated Sites (in Latvian: Piesārņoto un potenciāli piesārņoto vietu apzināšanas un reģistrācijas kārtība) ("LV", 171 (2558), 27.11.2001.) [in power from 28.11.2001.]; with Amendments.
National Register of Contaminated and Potentially Contaminated Sites (in Latvian: Piesārņoto un potenciāli piesārņoto vietu reģistrs). LVĢMC. Accessed: 07.04.2011. Available: http://oas.vdc.lv:7779/p_ppv.html
Burlakovs J., Klavins M. Stabilization and Solidification Technology Implementation in Latvia: First Studies. International Journal of Environmental Pollution and Remediation, vol. 1/issue 1, 2012.
Burlakovs J. and Vircavs M. Heavy Metal Remediation Technologies in Latvia: Possible Applications and Preliminary Case Study Results. Ecological Chemistry and Engineering, vol. 19/issue 4, pp 533-547, 2012.
National Register of Contaminated and Potentially Contaminated Sites (in Latvian: Piesārņoto un potenciāli piesārņoto vietu reģistrs). LVĢMC. Accessed: 07.04.2013. Available: http://oas.vdc.lv:7779/p_ppv.html
Burlakovs J., Vircavs M. (2011). Possible Applications of Soil Remediation Technologies in Latvia, Scientific Journal of Riga Technical University, vol. 7/issue 1, pp 46-53, 2012. GeoConference on Water Resources. Forest, Marine and Ocean Ecosystems
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