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PEAT HUMIC SUBSTANCES AS SORBENT FOR NANOMATERIALS

Dudare, stud. Diana, Klavins, Maris

First published: 2013-06-20https://doi.org/10.5593/sgem2013/bf6/s24.009View metrics

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Publication details

Title
PEAT HUMIC SUBSTANCES AS SORBENT FOR NANOMATERIALS
Authors
Dudare, stud. Diana, Klavins, Maris
Proceedings
SGEM International Multidisciplinary Scientific GeoConference EXPO Proceedings; 13th SGEM GeoConference NANO, BIO AND GREEN TECHNOLOGIES FOR A SUSTAINABLE FUTURE
Publisher
Stef92 Technology
Year
2013
Pages
67 - 74 pp
ISSN
1314-2704
ISBN
Not available yet
Language
en
Publication type
Conference Paper
Keywords
References50
  1. Tiller C.L. & O’Melia C.R. Natural organic matter and colloidal stability: models and measurements, Colloids and Surfaces A: Physicochemical and Engineering Aspects, vol. 73, pp 89– 102, 1993.

  2. Amal R., Raper J.A. & Waite T.D. Effect of fulvic acid adsorption on the aggregation kinetics and structure of hematite particles, Journal of Colloid and Interface Science, vol. 151, pp 244-257, 1992.

  3. Viota J.L., de Vicente J., Durán J.D.G. & Delgado A.V. Stabilization of magnetorheological suspensions by polyacrylic acid polymers, Journal of Colloid and Interface Science, vol. 284, pp 527-541, 2005.

  4. Moulin V. & Moulin C. Fate of actinides in the presence of humic substances under conditions relevant to nuclear waste disposal, Applied Geochemistry, vol. 10, pp 573-580, 1995.

  5. Benedetti M.F., van Riemsdijk W.H. & Koopal L.K. Humic substances considered as a heterogeneous Donnan gel phase. Environmental Science & Technology, vol. 30, pp 1805-1813, 1996.

  6. Pinheiro J.P., Mota A.M., d’Oliveira J.M.R. & Martinho J.M.G. Dynamic properties of humic matter by dynamic light scattering and voltammetry, Analytica Chimica Acta, vol. 329, pp 15-24, 1996.

  7. Roco M.C. & Bainbridge W.S. Societal implications of nanoscience and nanotechnology, National Science Foundation Report, pp 370, 2001.

  8. Schmid G. Nanoparticles: From Theory to Application, 1st Ed., Weinheim: Wiley-VCH, 2004.

  9. Poole C.P. & Owens F.J. Introduction to Nanotechnology, Hoboken: Wiley- Interscience, 2003.

  10. Klingshirn C. ZnO: material, physics and applications, ChemPhysChem, vol. 8, pp 782 –803, 2007.

  11. Gudkova A., Kienskaya K., Nazarov V., Kim V. & Mukhtarova S. Synthesis and use of highly dispersed zinc oxide, Russian Journal of Applied Chemistry, vol. 78, pp 1757–1760, 2005.

  12. Auffan M., Shipley H.J., Yean S., Kan A.T., Tomson M., Rose J. & Bottero J.Y. Nanomaterials as adsobents, In: Environmental Nanotechnology: Applications and GeoConference on Nano, Bio and Green – Technologies for a Sustainable Future Impacts of Nanomaterials (eds M.R. Wiesner & J.Y. Bottero.), pp 371 –392, McGraw- Hill, New York, 2007.

  13. Tombácz E. Adsorption: Theory, Modeling, and Analysis (eds J. Tóth), Dekker, New York, pp 711, 2002.

  14. Yavuz C.T., Mayo J.T., Yu W.W., Prakash A., Falkner J.C., Yean S., Cong L., Shipley H.J., Kan A., Tomson M., Natelson D. & Colvin V.L. Low-field magnetic separation of monodisperse Fe3O4 nanocrystals, Science, vol. 314, pp 964–967, 2006.

  15. Noubactep C. The fundamental mechanism of aqueous contaminant removal by metallic iron, Water SA, vol. 36, pp 663–670, 2010.

  16. Sammes N.M., Tompsett G.A., Nafe H. & Aldinger F. Bismuth based oxide electrolytes-structure and ionic conductivity, Journal of the European Ceramic Society, vol. 19, pp 1801–1826, 1999.

  17. Moens L., Ruiz P., Delmon B. & Devillers M. Enhancement of total oxidation of isobutene on bismuth-promoted tin oxide catalysts, Catalysis Letters, vol. 46/issue 1 –2, pp 93–99, 1997.

  18. Tan K.H. Soil Sampling, Preparation, and Analysis, Second Ed., Taylor & Francis, N.Y., pp 326, 2005.

  19. Thurman E.M. & Malcolm R.L. Preparative isolation of aquatic humic substances, Environmental Science & Technology, vol. 15, pp 463-466, 1981.

  20. Schnitzer M. Organic matter characterization, In: Methods of soil analysis (eds R.H. Miller & D.R. Keeney), pp 581–594, Madison, W.I., 1982.

  21. Baalousha M ., Manciulea A ., Cumberland S ., Kendall K . & Lead J.R . Aggregation and surface properties of iron oxide nanoparticles: influence of pH and natural organic matter, Environmental Toxicology and Chemistry, vol. 27/issue 9, pp 1875-1882, 2008.

  22. Ringqvist L., Holmgren A. & Oborn I. Poorly humified peat as an adsorbent for metals in wastewater, Water Research, vol. 36, pp 2394-2404, 2002.

  23. Xu D., Xu J., Wu J. & Muhammad A. Studies on the phosphorus sorption capacity of substrates used in constructed wetland systems, Chemosphere, vol. 63 , pp 344-352, 2006.

  24. Pertusatti J. & Prado A.G.S. Buffer capacity of humic acid: thermodynamic approach, Journal of Colloid and Interface Science, vol. 314, pp 484-489, 2007.

  25. Zhang W., Rattanaudompol U., Li H. & Bouchard D. Effects of humic and fulvic acids on aggregation of aqu/nC 60 nanoparticles, Water Research, vol 47/issue 5, pp 1793-1802, 2013.

  26. Tiller C.L. & O’Melia C.R. Natural organic matter and colloidal stability: models and measurements, Colloids and Surfaces A: Physicochemical and Engineering Aspects, vol. 73, pp 89– 102, 1993.

  27. Amal R., Raper J.A. & Waite T.D. Effect of fulvic acid adsorption on the aggregation kinetics and structure of hematite particles, Journal of Colloid and Interface Science, vol. 151, pp 244-257, 1992.

  28. Viota J.L., de Vicente J., Durán J.D.G. & Delgado A.V. Stabilization of magnetorheological suspensions by polyacrylic acid polymers, Journal of Colloid and Interface Science, vol. 284, pp 527-541, 2005.

  29. Moulin V. & Moulin C. Fate of actinides in the presence of humic substances under conditions relevant to nuclear waste disposal, Applied Geochemistry, vol. 10, pp 573-580, 1995.

  30. Benedetti M.F., van Riemsdijk W.H. & Koopal L.K. Humic substances considered as a heterogeneous Donnan gel phase. Environmental Science & Technology, vol. 30, pp 1805-1813, 1996.

  31. Pinheiro J.P., Mota A.M., d’Oliveira J.M.R. & Martinho J.M.G. Dynamic properties of humic matter by dynamic light scattering and voltammetry, Analytica Chimica Acta, vol. 329, pp 15-24, 1996.

  32. Roco M.C. & Bainbridge W.S. Societal implications of nanoscience and nanotechnology, National Science Foundation Report, pp 370, 2001.

  33. Schmid G. Nanoparticles: From Theory to Application, 1st Ed., Weinheim: Wiley-VCH, 2004.

  34. Poole C.P. & Owens F.J. Introduction to Nanotechnology, Hoboken: Wiley- Interscience, 2003.

  35. Klingshirn C. ZnO: material, physics and applications, ChemPhysChem, vol. 8, pp 782 –803, 2007.

  36. Gudkova A., Kienskaya K., Nazarov V., Kim V. & Mukhtarova S. Synthesis and use of highly dispersed zinc oxide, Russian Journal of Applied Chemistry, vol. 78, pp 1757–1760, 2005.

  37. Auffan M., Shipley H.J., Yean S., Kan A.T., Tomson M., Rose J. & Bottero J.Y. Nanomaterials as adsobents, In: Environmental Nanotechnology: Applications and GeoConference on Nano, Bio and Green – Technologies for a Sustainable Future Impacts of Nanomaterials (eds M.R. Wiesner & J.Y. Bottero.), pp 371 –392, McGraw- Hill, New York, 2007.

  38. Tombácz E. Adsorption: Theory, Modeling, and Analysis (eds J. Tóth), Dekker, New York, pp 711, 2002.

  39. Yavuz C.T., Mayo J.T., Yu W.W., Prakash A., Falkner J.C., Yean S., Cong L., Shipley H.J., Kan A., Tomson M., Natelson D. & Colvin V.L. Low-field magnetic separation of monodisperse Fe3O4 nanocrystals, Science, vol. 314, pp 964–967, 2006.

  40. Noubactep C. The fundamental mechanism of aqueous contaminant removal by metallic iron, Water SA, vol. 36, pp 663–670, 2010.

  41. Sammes N.M., Tompsett G.A., Nafe H. & Aldinger F. Bismuth based oxide electrolytes-structure and ionic conductivity, Journal of the European Ceramic Society, vol. 19, pp 1801–1826, 1999.

  42. Moens L., Ruiz P., Delmon B. & Devillers M. Enhancement of total oxidation of isobutene on bismuth-promoted tin oxide catalysts, Catalysis Letters, vol. 46/issue 1 –2, pp 93–99, 1997.

  43. Tan K.H. Soil Sampling, Preparation, and Analysis, Second Ed., Taylor & Francis, N.Y., pp 326, 2005.

  44. Thurman E.M. & Malcolm R.L. Preparative isolation of aquatic humic substances, Environmental Science & Technology, vol. 15, pp 463-466, 1981.

  45. Schnitzer M. Organic matter characterization, In: Methods of soil analysis (eds R.H. Miller & D.R. Keeney), pp 581–594, Madison, W.I., 1982.

  46. Baalousha M ., Manciulea A ., Cumberland S ., Kendall K . & Lead J.R . Aggregation and surface properties of iron oxide nanoparticles: influence of pH and natural organic matter, Environmental Toxicology and Chemistry, vol. 27/issue 9, pp 1875-1882, 2008.

  47. Ringqvist L., Holmgren A. & Oborn I. Poorly humified peat as an adsorbent for metals in wastewater, Water Research, vol. 36, pp 2394-2404, 2002.

  48. Xu D., Xu J., Wu J. & Muhammad A. Studies on the phosphorus sorption capacity of substrates used in constructed wetland systems, Chemosphere, vol. 63 , pp 344-352, 2006.

  49. Pertusatti J. & Prado A.G.S. Buffer capacity of humic acid: thermodynamic approach, Journal of Colloid and Interface Science, vol. 314, pp 484-489, 2007.

  50. Zhang W., Rattanaudompol U., Li H. & Bouchard D. Effects of humic and fulvic acids on aggregation of aqu/nC 60 nanoparticles, Water Research, vol 47/issue 5, pp 1793-1802, 2013.

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