1 |
Influences of the operational variables on electrochemical treatment of chelated Cu(II) in alkaline solutions using a membrane cell Eivazihollagh A, Backstrom J, Norgren M, Edlund H Journal of Chemical Technology and Biotechnology, 92(6), 1436, 2017 |
2 |
Process optimization and modeling of heavy metals extraction from a molybdenum rich spent catalyst by Aspergillus niger using response surface methodology Gholami RM, Mousavi SM, Borghei SM Journal of Industrial and Engineering Chemistry, 18(1), 218, 2012 |
3 |
Selective recovery of copper, nickel and zinc from ashes produced from Saccharomyces cerevisiae contaminated biomass used in the treatment of real electroplating effluents Machado MD, Soares EV, Soares HMVM Journal of Hazardous Materials, 184(1-3), 357, 2010 |
4 |
Heavy metals recovery from industrial wastewater using Taguchi method Kaminari NMS, Schultz DR, Ponte MJJS, Ponte HA, Marino CEB, Neto AC Chemical Engineering Journal, 126(2-3), 139, 2007 |
5 |
Pyrolysis as a technique for separating heavy metals from hyperaccumulators. Part III: pilot-scale pyrolysis of synthetic hyperaccumulator biomass Koppolu L, Prasad R, Clements LD Biomass & Bioenergy, 26(5), 463, 2004 |
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Pyrolysis as a technique for separating heavy metals from hyperaccumulators. Part 1: Preparation of synthetic hyperaccumulator biomass Koppolu L, Clements LD Biomass & Bioenergy, 24(1), 69, 2003 |
7 |
Pyrolysis as a technique for separating heavy metals from hyperaccumulators. Part II: Lab-scale pyrolysis of synthetic hyperaccumulator biomass Koppolu L, Agblevor FA, Clements LD Biomass & Bioenergy, 25(6), 651, 2003 |