The catalytic activity of biological seeds and Acidithiobacillus ferrooxidans on the process of ammonium jarosite
Subject Areas : Microbial Biotechnology
Nasim Eftekhari
1
,
Mohammad Kargar
2
,
Farokh Rokhbakhsh Zamin
3
,
Nahid Rastakhiz
4
,
Zahra Manafi
5
1 - Ph.D. Candidate, Department of Microbiology, Kerman Branch, Islamic Azad University, Kerman, Iran
2 - Professor, Department of Microbiology, Jahrom Branch, Islamic Azad University, Jahrom, Iran,
3 - Assistant Professor, Department of Microbiology, Kerman Branch, Islamic Azad University, Kerman, Iran,
4 - Assistant Professor, Department of Chemistry, Kerman Branch, Islamic Azad University, Kerman, Iran,
5 - Ph.D. Candidate, National Iranian Copper Industries Co., Sarcheshmeh Mine, Iran
Keywords: Iron, Bioleaching, Jarosite, Acidithiobacillus ferrooxidans,
Abstract :
Background & Objectives: Ferric iron that commonly exists in the leaching solution needs to be removed before the recovery of copper bioleaching using methods such as jarosite seed. The objective of this study was to investigate the catalytic performance of biological seeds and Acidithiobacillus ferrooxidans in the process of jarosite formation via the biosynthesis process. Materials & Methods: Acidithiobacillus ferrooxidans was first grown in 9K medium. Jarosite seeds were synthesized using this bacterium. Then the effect of the biological activity of different seeds (5, 10 g/L) on jarosite formation was investigated. The type of jarosites synthesized was identified by X-ray diffraction (XRD), Fourier transforms infrared spectroscopy (FTIR), and scanning electron microscope (SEM) analysis. Meantime, the morphologies of jarosite crystals were studied. Results: The FTIR and XRD results showed that biosynthetic jarosite seeds are ammonium jarosite type. The amount of jarosite increased with increasing seed concentration and the induction time of precipitation decreased. The pH and Eh of culture medium with increasing seed decreased. Bacterial growth also decreased in the presence of jarosite seeds compared to medium without biological seeds. According to the results of SEM, The morphologies of ammonium jarosite crystals were significantly affected by the jarosite seeds. The jarosite crystals were precipitated with the presence of seeds that had a smooth, uniform, and larger surface than non- seeding jarosite. Conclusion: The results showed that the precipitation process of jarosite is more complete with biological seeds. The results of this study can improve the efficiency of the iron removal process in copper bioleaching and reduce production costs.
aspects of jarosite and its utilization potentials. Annales de Chimie Science des Matériaux.
2020; 44(1): 43-52.
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JA. Biooxidation and precipitation for iron and sulfate removal from heap bioleaching effluent
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promoted by Acidithiobacillus ferrooxidans. Plos one. 2015; 3: 1-12.
4. Zhu J, Gan M, Zhang D, Hu YH, Chai LY. The nature of schwertmannite and jarosite mediated
by two strains of Acidithiobacillus ferrooxidans with different ferrous oxidation ability.
Material Sci Eng. 2013; 33: 2679-2685.
5. Dutrizac J. The effect of seeding on the rate of precipitate of ammonium jarosite and sodium
jarosite. Hydrometallurgy. 1996; 42(3): 293-312.
6. Kazemi M J, Kargar M, Nowroozi J, Sepahi A, Doosti A, Manafi Z. The wide distribution of an
extremely thermoacidophilic microorganism in the copper mine at ambient temperature and
under acidic condition and its significance in bioleaching of a chalcopyrite concentrate. Revista
Argentina de Microbiologia. 2019; 51(1): 56-65.
7. Sasaki K, Konno H. Morphology of jarosite group compounds precipitated from biologically
and chemically oxidized Fe ions. Can Mineral. 2000; 38: 45-56.
8. Daoud J, Karamanev D. Formation of jarosite during Fe2+ oxidation by Acidithiobacillus
ferrooxidans. Minerals Eng. 2006; 19: 960-967.
9. Eftekhari N, Kargar M. Assessment of optimal iron concentration in the precipitation of jarosite
and the activity of Acidithiobacillus ferrooxidans. Modares Journal of biotechnology. 2018; 9
(4): 525-529 [In Persian].
10. Nemati M, Harrison STL, Hansford GS, Webb C. Biological oxidation of ferrous sulfate by
Thiobacillus ferrooxidans: A review on the kinetic aspects. Biochemical Engineering. 1998; 3:
171-190.
11. Liu JY, Xiu XX, Cai P. Study of formation of jarosite mediated by Thiobacillus ferrooxidans
in 9K medium. Procedia Earth Planetary Sci. 2009; 1: 706-712.
12. Sandy Jones F, Bigham JM, Gramp JP, Tuovinen OH. Formation and characterization of
ternary (Na, NH4, H3O) jarosites produced from Acidithiobacillus ferrooxidans cultures.
Appl Geochem. 2018; 91: 14-22.
13. Najorka J, Lewis J M T, Spratt J, Sephton M A. Single‑crystal X‑ray diffraction study of
synthetic sodium–hydronium jarosite. Phys Chem Minerals. 2016; 43: 377-386.
14. Gan M, Li MM, Zeng J, Liu XX, Zhu Jv, Hu YH, Qiu GZ. Acidithiobacillus ferrooxidans
enhanced heavy metals immobilization efficiency in acidic aqueous system through
bio-mediated coprecipitation. Transaction Nonferrous Metals Soc China. 2017; 27: 1156-1164.
15. Liu PF, Zhang YF. Crystallization of ammonium jarosite from ammonium ferric sulfate
solutions. Hydrometallurgy. 2019; 189: 1-8.
_||_
aspects of jarosite and its utilization potentials. Annales de Chimie Science des Matériaux.
2020; 44(1): 43-52.
2. Nurmi P, Özkaya B, Sasaki K, Kaksonen AH, Riekkola-Vanhanen M, Tuovinen OH, Puhakka
JA. Biooxidation and precipitation for iron and sulfate removal from heap bioleaching effluent
streams. Hydrometallurgy. 2010; 101(1-2): 7-14.
3. Hou Q, Fang D, Liang J, Zhou L. Significance of oxygen supply in jarosite biosynthesis
promoted by Acidithiobacillus ferrooxidans. Plos one. 2015; 3: 1-12.
4. Zhu J, Gan M, Zhang D, Hu YH, Chai LY. The nature of schwertmannite and jarosite mediated
by two strains of Acidithiobacillus ferrooxidans with different ferrous oxidation ability.
Material Sci Eng. 2013; 33: 2679-2685.
5. Dutrizac J. The effect of seeding on the rate of precipitate of ammonium jarosite and sodium
jarosite. Hydrometallurgy. 1996; 42(3): 293-312.
6. Kazemi M J, Kargar M, Nowroozi J, Sepahi A, Doosti A, Manafi Z. The wide distribution of an
extremely thermoacidophilic microorganism in the copper mine at ambient temperature and
under acidic condition and its significance in bioleaching of a chalcopyrite concentrate. Revista
Argentina de Microbiologia. 2019; 51(1): 56-65.
7. Sasaki K, Konno H. Morphology of jarosite group compounds precipitated from biologically
and chemically oxidized Fe ions. Can Mineral. 2000; 38: 45-56.
8. Daoud J, Karamanev D. Formation of jarosite during Fe2+ oxidation by Acidithiobacillus
ferrooxidans. Minerals Eng. 2006; 19: 960-967.
9. Eftekhari N, Kargar M. Assessment of optimal iron concentration in the precipitation of jarosite
and the activity of Acidithiobacillus ferrooxidans. Modares Journal of biotechnology. 2018; 9
(4): 525-529 [In Persian].
10. Nemati M, Harrison STL, Hansford GS, Webb C. Biological oxidation of ferrous sulfate by
Thiobacillus ferrooxidans: A review on the kinetic aspects. Biochemical Engineering. 1998; 3:
171-190.
11. Liu JY, Xiu XX, Cai P. Study of formation of jarosite mediated by Thiobacillus ferrooxidans
in 9K medium. Procedia Earth Planetary Sci. 2009; 1: 706-712.
12. Sandy Jones F, Bigham JM, Gramp JP, Tuovinen OH. Formation and characterization of
ternary (Na, NH4, H3O) jarosites produced from Acidithiobacillus ferrooxidans cultures.
Appl Geochem. 2018; 91: 14-22.
13. Najorka J, Lewis J M T, Spratt J, Sephton M A. Single‑crystal X‑ray diffraction study of
synthetic sodium–hydronium jarosite. Phys Chem Minerals. 2016; 43: 377-386.
14. Gan M, Li MM, Zeng J, Liu XX, Zhu Jv, Hu YH, Qiu GZ. Acidithiobacillus ferrooxidans
enhanced heavy metals immobilization efficiency in acidic aqueous system through
bio-mediated coprecipitation. Transaction Nonferrous Metals Soc China. 2017; 27: 1156-1164.
15. Liu PF, Zhang YF. Crystallization of ammonium jarosite from ammonium ferric sulfate
solutions. Hydrometallurgy. 2019; 189: 1-8.
