[1. GERNÁTOVÁ, M., JANDERKA, P. 2006. Elektrochemická degradácia chlórfenolov. (Electrochemical degradation of chlorophenols). Brno: Chem. Listy 100, pp. 877-881.]Search in Google Scholar
[2. VLKOVÁ, L., CÍRKVA, V. 2005. Chlorované fenoly a způsoby jejich degradace. (Chlorinated phenols and its degradation processes). Praha: Chem. Listy 99, pp. 125-130.]Search in Google Scholar
[3. HIND, A. R., BHARGAVA, S. K., GROCOTT, S. C. 1999. The surface chemistry of Bayer process solids: a review. In: Colloids and Surfaces A: Physicochemical and Engineering Aspects, 146(1-3), pp. 359-374.]Search in Google Scholar
[4. CENGEL, P. 1996. Niekoľko poznámok k spracovaniu kalov po výrobe hliníka. (Several remarks on the treatment of sludge from aluminium production). In: Životné prostredie, Issue 5. ISSN 0044-4863]Search in Google Scholar
[5. SCHWARZ, M., LALÍK, V. 2011. Biologické účinky, vylúhovateľnosť a testovanie ekotoxicity odpadového kalu z výroby oxidu hlinitého. (Biological effects, leachability and ecotoxicity testing of sewage sludge from alumina production). Chem. Listy 105. pp. 518-523.]Search in Google Scholar
[6. WANG, P., LIU, D. 2012. Physical and Chemical Properties of Sintering Red Mud and Bayer Red and the Implications for Benefical Utilization. In: Materials, 5, pp. 1800-1810. ISSN 1996-194410.3390/ma5101800]Search in Google Scholar
[7. MICHAELI, E. et al. 2012. Skládka priemyselného odpadu lúženca ako príklad environmentálnej záťaže pri bývalej Niklovej hute v Seredi. (Landfill industrial waste from black nickel mud as an example of environmental burden in the former nickel smelter in Sereď). In: Životné prostredie,46(2), pp. 63-68.]Search in Google Scholar
[8. MICHAELI, E., BOLTIŽIAR, M. 2010. Vybrané lokality environmentálnych záťaží v Slovenskej republike. (Selected locations of environmental burdens in Slovakia). [cit. 2014-01-03]. Available on the Internet: http://geografia.science.upjs.sk/images/geographia_cassoviensis/articles/GC-2010-4-2/19Michaeli_Boltiziar.pdf]Search in Google Scholar
[9. SOLDÁNOVÁ, Z., SOLDÁN, M., ČAPLOVIČ, L. 2009. Štúdium kinetiky adsorpcie CrVI červeným kalom a lúžencom. (CrVI adsorption kinetics study of red mud and black nickel mud). In: Waste forum, Issue 2, pp. 58-65.]Search in Google Scholar
[10. FCPS. Common duckweed. [cit. 2013-10-17]. Available on the Internet: http://www.fcps.edu/islandcreekes/ecology/duckweed.htm]Search in Google Scholar
[11. ROOK. Lesser duckweed. [cit. 2013-10-17]. Available on the Internet: http://www.rook.org/earl/bwca/nature/aquatics/lemna.html]Search in Google Scholar
[12. AQUATICPLANTCENTRAL. Lemna minor. [cit. 2013-10-17]. Available on the Internet: http://www.aquaticplantcentral.com/forumapc/plantfinder/details.php?id=131]Search in Google Scholar
[13. MISSOURI BOTANICAL GARDEN. Lemna minor. [cit. 2014-01-03]. Available on the Internet: http://www.missouribotanicalgarden.org/PlantFinder/PlantFinderDetails.aspx?kempercode=a622]Search in Google Scholar
[14. AQUAPLANT. Common Duckweed. [cit. 2013-10-17]. Available on the Internet: http://aquaplant.tamu.edu/plant-identification/alphabetical-index/common-duckweed/]Search in Google Scholar
[15. SINGH, S., PRADHAN, S., RAI, L. C. 2000. Metal removal from single and multimetallic systems by different biosorbent materials as evaluated by differential pulse anodic stripping voltammetry. Elsevier. Department of Botany, Laboratory of Algal Biology, Banaras Hindu University. Process Biochemistry 36. pp. 175-182.]Search in Google Scholar
[16. MIRETZKY, P., SARALEGUI, A., CIRELLI, A. F. 2006. Simultaneous heavy metal removal mechanism by dead macrophytes. In: Chemosphere 62, pp. 247-254.]Search in Google Scholar
