Effect of oxygen limitation on solid-bed bioleaching of heavy metals from contaminated sediments

• Published in: Chemosphere (Oxford) Vol. 65; no. 1; pp. 102 - 109
• Main Authors: Seidel, Heinz, Görsch, Kati, Schümichen, Antje
• Format: Journal Article
• Language: English
• Published: Oxford Elsevier Ltd 01.09.2006; Elsevier
• Subjects: Applied sciences; Biodegradation of pollutants; Biodegradation, Environmental; Bioleaching; Biological and medical sciences; Biotechnology; Decontamination. Miscellaneous; Earth sciences; Earth, ocean, space; Engineering and environment geology. Geothermics; Environment and pollution; Environmental Pollutants - analysis; Exact sciences and technology; Fundamental and applied biological sciences. Psychology; Geologic Sediments - chemistry; Geologic Sediments - microbiology; Heavy metals; Hydrogen-Ion Concentration; Industrial applications and implications. Economical aspects; Metals, Heavy - analysis; Oxidation-Reduction; Oxygen - chemistry; Oxygen limitation; Pollution; Pollution, environment geology; Sediment; Soil and sediments pollution; Solid bed; Sulfur - chemistry; Bioleaching; Sediment; Solid bed; Oxygen limitation; Heavy metals; Laboratory study; Oxygen; In situ; Biostimulation; Bacterial leaching; Sediments; Heavy metal; Pollution; Decontamination; Limiting factor; Bioremediation
• ISSN: 0045-6535; 1879-1298
• DOI: 10.1016/j.chemosphere.2006.02.022

The effects of oxygen limitation on solid-bed bioleaching of heavy metals (Me) were studied in a laboratory percolator system using contaminated sediment supplemented with 2% elemental sulfur (S o). Oxygen limitation was realized by controlling the gas flow and oxygen concentration in the aeration gas. The oxygen supply varied between 150 and 0.5 mol O 2 mol S o - 1 over 28 d of leaching. Moderate oxygen limitation led to temporarily suppression of acidification, rate of sulfate generation and Me solubilization. Lowering the oxygen supply to 0.5 mol O 2 mol S o - 1 resulted in retarding acidification over a period of three weeks and in poor Me solubilization. Oxidation of S o occurred even under strong oxygen limitation at a low rate. High surplus of oxygen was necessary for almost complete oxidation of the added S o. The maximum Me solubilization was reached at an oxygen supply of 7.5 mol O 2 mol S o - 1 . Thus, the oxygen input during solid-bed bioleaching can be reduced considerably by controlling the gas flow without loss of metal removal efficiency. Oxygen consumption rates, ranging from 0.4 × 10 −8 to 0.8 × 10 - 8 kg O 2 kg dm - 1 s - 1 , are primarily attributed to high reactivity of the sulfur flower and high tolerance of indigenous autotrophic bacteria to low oxygen concentrations. The S o related oxygen consumption was calculated assuming a molar yield coefficient Y O 2 / S of 1.21. The oxygen conversion degree, defined as part of oxygen feed consumed by S o oxidation, increased from 0.7% to 68% when the oxygen supply was reduced from 150 to 0.5 mol O 2 mol S o - 1 .