GARD Guide Literature Database -- Query Results

Skousen, J., Rose, A., Geidel, G., Foreman, J., Evans, R., & Hellier, W. (1998). A handbook of technologies for avoidance and remediation of acid mine drainage. Keywords: acid mine drainage bioremediation coal mines constructed wetlands disposal barriers ion exchange mines pollution pumping recharge remediation reverse osmosis surface water technology waste disposal waste management water treatment wetlands 22, Environmental geology https://www.Wolkersdorfer.info/gard/refbase/show.php?record=245
Schwartz, M. O., & Ploethner, D. (1999). From mine water to drinking water; heavy-metal removal by carbonate precipitation in the Grootfontein-Omatako Canal, Namibia.. Hanover: Bundesanst. fuer Geowiss. und Rohstoffe. Keywords: Africa; aluminum; cadmium; canals; carbonates; copper; drinking water; geochemistry; Grootfontein-Omatako Canal; heavy metals; hydrochemistry; iron; lead; manganese; metallogenic provinces; metals; mine drainage; mineral deposits, genesis; mines; Namibia; policy; precipitation; purification; Southern Africa; transport; water management; water treatment 22, Environmental geology https://www.Wolkersdorfer.info/gard/refbase/show.php?record=250
Scharp, R. A., Kawahara, F., Burckle, J., Allan, J., & Govind, R. (2002). Recovery of metals from acid mine drainage Hardrock mining 2002; issues shaping the industry.. Keywords: acid mine drainage; bacteria; Berkeley Pit; Butte Montana; cost; decontamination; metals; mining; Montana; pH; pollution; recovery; remediation; Silver Bow County Montana; smelting; sulfates; United States 22, Environmental geology https://www.Wolkersdorfer.info/gard/refbase/show.php?record=251
Sastri, V. S. (1975). Reverse osmosis for the treatment of metal waste solutions. Canada Centre For Mineral And Energy Technology Scientific Bulletin, 75-07, 18. https://www.Wolkersdorfer.info/gard/refbase/show.php?record=254
Sapsford, D., Barnes, A., Dey, M., Williams, K., Jarvis, A., & Younger, P. (2007). (R. Cidu, & F. Frau, Eds.). Water in Mining Environments. Cagliari: Mako Edizioni. Abstract: This paper presents iron removal data from a novel low footprint mine water treatment system. The paper discusses possible design configurations and demonstrates that the system could treat 1 L/s of mine water containing 8.4 mg/L of iron to < 1 mg/L with a system footprint of 66 m2. A conventional lagoon and aerobic wetland system would require at least 160 m2 to achieve the same treatment. Other advantages of the system are that it produces a clean and dense sludge amenable to on-site storage and possible recycling and that heavy plant will generally not be required for construction. Keywords: passive treatment iron mine water https://www.Wolkersdorfer.info/gard/refbase/show.php?record=255

Skousen, J., Rose, A., Geidel, G., Foreman, J., Evans, R., & Hellier, W. (1998). A handbook of technologies for avoidance and remediation of acid mine drainage.

Schwartz, M. O., & Ploethner, D. (1999). From mine water to drinking water; heavy-metal removal by carbonate precipitation in the Grootfontein-Omatako Canal, Namibia.. Hanover: Bundesanst. fuer Geowiss. und Rohstoffe.

Scharp, R. A., Kawahara, F., Burckle, J., Allan, J., & Govind, R. (2002). Recovery of metals from acid mine drainage Hardrock mining 2002; issues shaping the industry..

Sastri, V. S. (1975). Reverse osmosis for the treatment of metal waste solutions. Canada Centre For Mineral And Energy Technology Scientific Bulletin, 75-07, 18.

Sapsford, D., Barnes, A., Dey, M., Williams, K., Jarvis, A., & Younger, P. (2007). (R. Cidu, & F. Frau, Eds.). Water in Mining Environments. Cagliari: Mako Edizioni.