Nowatorskie rozwiązania w pozyskiwaniu i przeróbce metali ciężkich

• Autorzy: Pawlik T.
• Języki publikacji: PL

Słowa kluczowe

PL

biogórnictwo; mikrobiologiczne pozyskiwanie metali; bioługowanie; fitogórnictwo

• Wydawca: Wydawnictwo Lektorium
• Czasopismo: Ekotechnika
• Rocznik: 2007
• Tom: nr 3-4
• Strony: 53--55
• Opis fizyczny: Bibliogr. 19 poz., fot.

Twórcy

autor

Pawlik T.

• Wydział Nauk o Ziemi i Kształtowania Środowiska, Uniwersytet Wrocławski

Bibliografia

• [1] Anderson C.W.N., Brooks R.R., Chiarucci A., LaCoste C.J., Leblanc M., Robinson B.H., Simcock R., Steward R.B.: Phytomining for thallium, nickel and gold, J. Geochem, Explor., 1999, 67, s. 407-415.
• [2] Blaylock M.J., Salt D.E., Dushenkov, S., Zakharova, O., Gussman, C., Kapulnik, Y., Ensley, B.D., Raskin, I.: Enhanced accumulation of Pb in Indian mustard by soil-applied chelating agents, Environ. Sci. Technol. 31, 1997, s. 860-865.
• [3] Brierley J.A.: Biooxidation Pretreatment of Refractory Sulfidic and Sulfidic-Carbonaceous Gold Ores and Concentrates, [w:] L.H. Filipek, G.S. Plumlee (eds.), The Environmental Geochemistry of Mineral Deposits, Part B. Case Studies and Research Topics. Soc. Of Econ. Geologists. Rev. in Econ. Geology, 1999, 6B, s. 539-547.
• [4] Brierley J.A., Brierley C.L.: Present and future commercial applications of biohydrometallurgy, Hydrometallurgy 59,2001, s. 233-239.
• [5] Gałuszka A.: The use of microorganisms and plants to metal extracting, Przegl. Geol. 53 (10) 2005.
• [6] Hansford G.S., Bailey A.D.: The logistic equation for modeling bacterial oxidation kinetics, Minerals Engineering 5, 1992, s. 1355-1364.
• [7] Komnitas C., Pooley F.D.: Optimization of the bacterial oxidation of an arsenical gold sulphide concentrate from Olympias, Greece, Minerals Engineering 4(12) 1991, s. 1297-1303.
• [8] Koehler F.E.: Medicinal Plants, 1887.
• [9] Migaszewski Z. M., Gałuszka A.: Podstawy geochemii środowiska, Wyd. Nauk.-Techn., Warszawa 2007.
• [10] Nasernejad B., Kaghazchi T., Edrisi M., Sohrabi M.: Bioleaching of molybdenum from low-grade copper ore, Process Biochemistry 35, 1999, s. 437-440.
• [11] Nordstrom D.K., Alpers C.N.. Geochemistry of Acid Mine Waters, [w:] G.S. Plumlee & J.J. Logsdon (eds.) - The Environmental Geochemistry of Mineral Deposits, Part A. Processes, Techniques, and Health Issues. Soc. of Econ. Geologists, Rev. in Econ, Geology 6A, 1999, s. 133-160.
• [12] Olson G.J., Brierley J.A., Brierley C.L.: Bioleaching review part B: Progress in bioleaching: application of microbial processes by the minerals industries, Appl. Microbiol. Biotechnol. 63, 2003, s. 249-257.
• [13] Pinches A.: Bacterial leaching of an arsenic-bearing sulphide concentrate, [w:] A.R. Burkin (ed.) - Leaching and Reduction in Hydrometallurgy, The Institute of Mining and Metallurgy London 1975, s. 28-35.
• [14] Rawlings D.E.: Industrial practice and the biology of leaching of metals from ores, The 1997 Pan Labs Lecture, J. Industrial Microbiol. & Biotechn. 20, 1998: s. 268-274.
• [15] Rawlings D.E., Dew D., Du Plesis C.: Biomineralization of metal-containing ores and concentrates, Trends in Biotechnology 21, 2003: s. 38-44.
• [16] Robinson, B.H., Brooks, R.R., Howes, A. W., Kirkman, J.H., Gregg, P.E.H.: The potential of the high-biomass Berkheya coddii for phytoremediation and phytomining, J. Geochem. Explor. 60, 1997, s. 115-126.
• [17] Sadowski Z., Jazdzyk E., Karas H.: Bioleaching of copper ore flotation concentrates, Mineral Engineering 16, 2003, s. 51-53.
• [18] www. inl.gov.
• [19] www. soilprot.ethz.ch