| 1 - 1 |
Biohydrometallurgy Foreword
Wills BA |
| 2 - 5 |
Biomining in reverse gear: Using bacteria to extract metals from oxidised ores
Johnson DB, du Plessis CA |
| 6 - 13 |
Investigating the effect of acid stress on selected mesophilic micro-organisms implicated in bioleaching
Ngoma IE, Ojumu TV, Harrison STL |
| 14 - 25 |
Effect of physico-chemical and operating conditions on the growth and activity of Acidithiobacillus ferrooxidans in a simulated heap bioleaching environment
Govender E, Bryan CG, Harrison STL |
| 26 - 31 |
The effect of flotation and parameters for bioleaching of printed circuit boards
Makinen J, Bacher J, Kaartinen T, Wahlstrom M, Salminen J |
| 32 - 37 |
Engineered strains enhance gold biorecovery from electronic scrap
Natarajan G, Tay SB, Yew WS, Ting YP |
| 38 - 44 |
Leaching of copper from Kupferschiefer by glutamic acid and heterotrophic bacteria
Kostudis S, Bachmann K, Kutschke S, Pollmann K, Gutzmer J |
| 45 - 53 |
Co-processing of sulfidic mining wastes and metal-rich post-consumer wastes by biohydrometallurgy
Guezennec AG, Bru K, Jacob J, d'Hugues P |
| 54 - 62 |
Possibilities for Co(III) dissolution from an oxidized ore through simultaneous bioleaching of pyrite
Zeka L, Lambert F, Frenay J, Gaydardzhiev S, IlungaNdala A |
| 63 - 69 |
Fundamental aspects of hematite flotation using the bacterial strain Rhodococcus ruber as bioreagent
Lopez LY, Merma AG, Torem ML, Pino GH |
| 70 - 76 |
SEM and EDS observations of carrollite bioleaching with a mixed culture of acidophilic bacteria
Nkulu G, Gaydardzhiev S, Mwema E, Compere P |
| 77 - 84 |
Iron solubilization during anaerobic growth of acidophilic microorganisms with a polymetallic sulfide ore
Norris PR, Gould OJP, Ogden TJ |
| 85 - 93 |
Start-up, adjustment and long-term performance of a two-stage bioremediation process, treating real acid mine drainage, coupled with biosynthesis of ZnS nanoparticles and ZnS/TiO2 nanocomposites
Vitor G, Palma TC, Vieira B, Lourenco JP, Barros RJ, Costa MC |
| 94 - 99 |
Recovery of indium from sphalerite ore and flotation tailings by bioleaching and subsequent precipitation processes
Martin M, Janneck E, Kermer R, Patzig A, Reichel S |
| 100 - 109 |
Impact of organic carbon on the leachability of vanadium, manganese, iron and molybdenum from shale residues
Sjoberg V, Karlsson S |
| 110 - 115 |
Effect of thiocyanate on BIOX (R) organisms: Inhibition and adaptation
van Hille RP, Dawson E, Edward C, Harrison STL |
| 116 - 125 |
Bioleaching of Kupferschiefer blackshale - A review including perspectives of the Ecometals project
Kutschke S, Guezennec AG, Hedrich S, Schippers A, Borg G, Kamradt A, Gouin J, Giebner F, Schopf S, Schlomann M, Rahfeld A, Gutzmer J, D'Hugues P, Pollmann K, Dirlich S, Bodenan F |
| 126 - 132 |
Salt-tolerant microorganisms potentially useful for bioleaching operations where fresh water is scarce
Rea SM, McSweeney NJ, Degens BP, Morris C, Siebert HM, Kaksonen AH |
| 133 - 139 |
Biotreatment of As-containing simulated acid mine drainage using laboratory scale sulfate reducing upflow anaerobic sludge blanket reactor
Sahinkaya E, Yurtsever A, Toker Y, Elcik H, Cakmaci M, Kaksonen AH |
| 140 - 145 |
Biosorptive flotation of copper ions from dilute solution using BSA-coated bubbles
Nazari AM, Cox PW, Waters KE |
