Comparison of Copper Dissolution in Chalcopyrite Concentrate Bioleaching with Acidianus Brierleyi in Different Initial pH Values

IF 1.1 Q3 MINING & MINERAL PROCESSING Journal of Mining and Environment Pub Date : 2020-05-20 DOI:10.22044/JME.2020.9447.1853
M. Yazdi, M. Abdollahi, S. Mousavi, A. Darban
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Abstract

Although bioleaching of chalcopyrite by thermophilic microorganisms enhances the rate of copper recovery, a high temperature accelerates iron precipitation as jarosite, which can bring many operational problems in the industrial processes. In this research work, the bioleaching of chalcopyrite concentrate by the thermophilic Acidianus brierleyi was studied, and the microbial growth, copper dissolution, iron oxidation, and jarosite precipitation were monitored in different initial pH (pHi) values. Bacterial growth was greatly affected by pHi. While the bacterial growth was delayed for 11 days with a pHi value of 0.8, this delay was reduced to nearly one day for a pHi value of 1.2. Two stages of copper recovery were observed during all the tests. A high pHi value caused a fast bacterial growth in the first stage and severe jarosite precipitation in the later days causing a sharp decline in the bacterial population and copper leaching rate. The copper recoveries after 11 days were 25%, 78%, 84%, 70%, 56%, and 39% for the pHi values of 0.8, 1.0, 1.2, 1.3, 1.5, and 1.7, respectively. Sulfur and jarosite were the main residues of the bioleaching tests. It was revealed that the drastic effect of jarosite precipitation on the microbial growth and copper recovery was mainly caused by the ferric iron depletion from solution rather than passivation of the chalcopyrite surface. A slow precipitation of crystalline jarosite did not cause a passive chalcopyrite surface. The mechanisms of chalcopyrite bioleaching were discussed.
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不同初始pH值下Brierleyi酸菌浸出黄铜矿精矿中铜的溶解比较
虽然嗜热微生物对黄铜矿的生物浸出提高了铜的回收率,但高温会加速铁以黄铁矾的形式析出,这在工业过程中会带来许多操作问题。研究了嗜热brierleyi酸菌对黄铜矿精矿的生物浸出,并对不同初始pH (pHi)值下微生物的生长、铜的溶解、铁的氧化和黄铁矾的沉淀进行了监测。细菌生长受pHi影响较大。当pHi值为0.8时,细菌生长延迟了11天,当pHi值为1.2时,细菌生长延迟缩短到近一天。在所有试验中都观察到两个阶段的铜回收。较高的pHi值导致初期细菌生长迅速,后期黄钾铁矾沉淀严重,导致细菌数量和铜浸出率急剧下降。当φ为0.8、1.0、1.2、1.3、1.5、1.7时,铜的回收率分别为25%、78%、84%、70%、56%、39%。硫和黄钾铁矾是生物浸出试验的主要残留物。结果表明,黄钾铁矾沉淀对微生物生长和铜回收率的显著影响主要是由于溶液中铁的耗尽而不是黄铜矿表面的钝化。缓慢沉淀结晶黄钾铁矾不会导致被动黄铜矿表面。探讨了黄铜矿生物浸出机理。
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来源期刊
Journal of Mining and Environment
Journal of Mining and Environment MINING & MINERAL PROCESSING-
CiteScore
1.90
自引率
25.00%
发文量
0
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