STUDY ON THE EFFECT OF BIOOXIDATION OF CLAY TYPE GOLD WASTE MINERAL USING Bacillus aryabhattai STRAIN SKC-5 ON GOLD RECOVERY THROUGH CYANIDATION
Considering the decrease of the non-refractory gold ore availability, the refractory gold ore began to be processed. However, to process refractory gold ore, a pretreatment process is needed to increase the gold extraction which leads to the biooxidation development. In this study, biooxidation e...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/39856 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Considering the decrease of the non-refractory gold ore availability, the refractory
gold ore began to be processed. However, to process refractory gold ore, a pretreatment
process is needed to increase the gold extraction which leads to the
biooxidation development. In this study, biooxidation experiment was investigated
on clay-type gold waste mineral that is mineral part of overburden, precisely in the
core soil layer which contains gold as well as impurity minerals such as sulfide,
carbonate, and clay minerals using iron- and sulfur-oxidizing bacteria..
A series of experiments was first started with ore grinding using a Ball Mill,
followed by sieving to obtain a particle size of passing 75 microns (-75 ?m). Later,
the ore was homogenized and sampled for the purposes of characterization and
biooxidation experiments. Prior to biooxidation experiments, a bacterial growth
curve was constructed to determine the optimum incubation time of bacteria used
for the next experiment. Direct cyanidation experiment was also carried out to the
ore without biooxidation to determine the effect of the biooxidation process in
increasing the gold extraction. Then, a preliminary biooxidation experiment was
conducted to determine the most optimum bacteria. After that, core biooxidation
experiments were carried out with the most optimum bacteria with several
variations including bacterial inoculum concentration, pyrite (FeS2) concentration,
and iron sulfate (FeSO4.7H2O) concentration.
The results showed that the refractory gold ore dominantly contained quartz and
calcite mineral as ore impurities. The gold particles were micro-sized and included
in sulfide minerals. The percent of preg-robbing of the gold ore obtained is 72,55%.
Gold extraction after direct cyanidation was approximately 76,57%. The
preliminary biooxidation experiment using the most optimum was able to enhance
the gold extraction up to 88,61%. Optimization of biooxidation experiment has
significantly increase the gold extraction about 90,37% under the most optimum
conditions : 5% (v/v) bacterial inoculum, 9 g/l pyrite (FeS2), and 6,7 g/l iron sulfide
(FeSO4.7H2O). This study suggested that biooxidation pre-treatment has been
proven as a low-cost and environmentally friendly method to enhance the gold
extraction for the refractory gold ore and thus, is potentially applicable to the field
scale with further optimization. |
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