Results 271 to 280 of about 1,200,876 (308)
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Aerobic bio‐oxidation of post‐anaerobic tannery effluents

International Journal of Environmental Studies, 1993
Wastewater generated from an industrial estate accommodating chrome as well as vegetable tanneries has a significant pollution potential with COD ranging from as low as 2000 mg/L to as high as 10,000 mg/L. This medium strength wastewater, if segregated from soak liquor and subjected to chromium removal/recovery, can very well be treated anaerobically ...
T. Nandy, S.N. Kaul, R. A. Daryapurkar
openaire   +1 more source

Bio-oxidation of minerals in air-lift loop bioreactors

International Journal of Mineral Processing, 2001
Abstract The high rate bio-oxidation of minerals in tanks has received a great deal of interest over the last decades. So far, aerated stirred tank reactors, which are common in the mining industry, have been used for these processes. However, as we are dealing with a biological system, it makes sense to apply reactor types that are especially ...
R. Ruitenberg   +2 more
openaire   +1 more source

Influence of poisonous gases on the bio-oxidation of coalmine gas

International Journal of Mining, Reclamation and Environment, 2009
Carbon monoxide (CO), hydrogen sulphide (H2S) and sulphur dioxide (SO2), which commonly appear and mix in coalmine gas, were investigated in terms of their effects on methane oxidation of methanotroph systems using single-factor and multi-factor experiments.
H. X. Yu, H. Min, Z. M. Lv, J. Liu
openaire   +1 more source

Review on the Bio-oxidation of Pyrite: Implications for the Mining Industry

2020
Pyrite (FeS2) is the most abundant and widely spread iron-containing sulfide mineral in the earth, and it is also an important source of sulfuric acid (H2SO4) and is commonly associated with the other valuable minerals as gangue mineral. Hence, it cannot be ignored in the modern industry, especially in the mining industry. Bio-oxidation of pyrite is an
Xin Lv   +6 more
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Studies on bio-oxidation of coal mine gas by a biofilter

Journal of Coal Science and Engineering (China), 2010
A new biofilter technology was used to control the methane concentration in the coal mine. The results indicate that the biofilter achieves a steady methane removal capacity of 1 470 mg/(L·h) after 30 days start-up. More than 90% of the methane can be removed with an empty bed retention time (EBRT) of 5.6 min when the inlet concentration of methane ...
Hai-xia Yu, Hang Min, Zhen-mei Lü
openaire   +1 more source

Processing of Arsenopyritic Gold Concentrates by Partial Bio-Oxidation Followed by Bioreduction

Environmental Science & Technology, 2011
Gold is commonly liberated from sulfide minerals by chemical and biological oxidation. Although these technologies are successful, they are costly and produce acidic waste streams. Removal of mineral-sulfur to overcome the mineralogical barrier could also be done by bioreduction, producing hydrogen sulfide (H(2)S).
Hol, A.   +4 more
openaire   +3 more sources

Bio-Oxidation Pretreatment

2023
Yang Hongying, Xu Kuangdi
openaire   +1 more source

Surface Characteristic of Pyrrhotite Bio-Oxidized by Acidithiobacillus Ferrooxidans

Advanced Materials Research, 2011
This paper deals with the surface characteristic of pyrrhotite bio-oxidized byAcidithiobacillus ferrooxidans. Large amounts of jarosite and element sulfur were determined in the bio-oxidation processe of pyrrhotite. More complicatedly, biofilm exists on the surface of pyrrhotite. This type of structured community ofA.
openaire   +1 more source

Applying bio-oxidation waste solution into two-stage oxidation process to enhance the bio-oxidation of pyrite: Insight on enhanced mechanism

Journal of Water Process Engineering, 2023
Shiqi Zhang   +5 more
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Elemental Tritium Analysis by Bio-oxidation

Health Physics, 1980
J C, McFarlane   +2 more
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