ArticleName |
Enhancement of chemically bound gold recovery in post-activation heap leaching of refractory ore |
ArticleAuthorData |
Sergo Ordzhonikidze Russian State University for Geological Prospecting, Moscow, Russia:
O. S. Bryukhovetsky, Professor, Doctor of Engineering Sciences, bos.rggru@mail.ru
Institute of Mining, Far East Branch, Russian Academy of Sciences, Khabarovsk, Russia1 ; Transbaikal State University, Chita, Russia2:
A. G. Sekisov1,2, Deputy Director, Doctor of Engineering Sciences
Institute of Mining, Far East Branch, Russian Academy of Sciences, Khabarovsk, Russia:
A. V. Rasskazova, Leading Researcher, Candidate of Engineering Sciences
Transbaikal State University, Chita, Russia1; Institute of Mining’s Chita Division, Siberian Branch, Russian Academy of Sciences, Chita, Russia2:
A. Yu. Lavrov1,2, Dean, Candidate of Engineering Sciences |
Abstract |
This article discusses the main problems connected with heap leaching of chemically bound gold during mining refractory complex ores. It is proposed to prepare refractory ores for heap leaching by electrochemical and photochemical activation of solutions of oxidizing and complexing reagents. The composition of solutions is determined by the mineral composition of the ores. Dispersed and chemically bound gold can occur in various forms in the ores of the sulfide, sulfide–carbonaceous and sulfide–quartz genesis. Therefore, various oxidizing agents should be used when preparing ores for heap leaching. Oxidizing agents actively interact with ore-forming elements that have direct or indirect chemical bonds with clustered gold atoms. Depending on the modes of occurrence of chemically bound dispersed gold, governed by its geochemical associations with the ore-forming minerals, it is proposed to carry out oxidative preparation of refractory ores both at the stage of blasting operations and during pelletizing (agglomeration). Oxidative preparation is implemented with electro-photo-activated solutions with hydroxide-peroxide, sulfuric acid-peroxide, carbonateperoxide, hydroxychloride, sulfuric acid-nitrite-nitrate base. Direct heap leaching of chemically bound gold is proposed to carry out after oxidative treatment with activated solutions. The oxidative treatment includes irrigation of mineral piles with concentrated activated solutions and, then with electrochemically treated water or activated weakly concentrated solution of a complexing agent. Commercial-scale application of heap leaching with oxidation pre-activation in gold ore mining can enable efficient concentration of low-grade difficult ore. In this case, depending on mineral paragenesis of ore and geochemical association of disperse gold, the proposed post-activation heap leaching technology can use process solutions composed of different reagents both at the stage of blasting and during irrigation or pelletizing. |
References |
1. Chen L., Yang T., Liu W., Wang D. Developments of processing technologies for refractory gold ores. Proceedings of the 4th International Symposium on High-Temperature Metallurgical Processing. John Wiley & Sons, Inc., 2013. pp. 545–551. 2. Celep O. Effect of flotation and potassium hydroxide pretr eatment of an antimonial refractory ore on the extraction of silver by cyanidation. Minerals Engineering. 2021. Vol. 172. 107171. DOI: 10.1016/j.mineng.2021.107171 3. Novgorodova М. I. Nanocrystals of native gold and their intergrowth. Novye dannye o mineralakh. 2004. Vol. 39. pp. 83–93. 4. Vikentiev I. V., Abramova V. D., Ivanova Yu. N., Tyukova E. E., Kovalchuk E. V., Bortnikov N. S. Trace Elements in Pyrite from the Petropavlovsk Gold-Porphyry Deposit (Polar Urals): Results of LA-ICP-MS Analysis. Doklady Earth Sciences. 2016. Vol. 470, Iss. 1. pp. 976–980. 5. Fedotov P. K., Senchenko A. E., Fedotov K. V., Burdonov A. E. The Krasnoyarsk Territory primary and complex gold rebellious ores dressability studies. Obogashchenie Rud. 2017. No. 3. pp. 21–26. DOI: 10.17580/or.2017.03.04 6. Fedotov P. K., Senchenko A. E., Fedotov K. V., Burdonov A. E. Dressability study for polymetallic ore deposits of the Zabaikalye Territory. Obogashchenie Rud. 2019. No. 3. pp. 3–9. DOI: 10.17580/or.2019.03.01 7. Genkin A. D., Wagner F. E., Krylova T. L., Tsepin A. I. Gold-bearing arsenopyrite and its formation condition at the Olympiada and Veduga gold deposits (Yenisei range, Siberia). Geology of Ore Deposits. 2002. Vol. 44, No. 1. pp. 52–68. 8. Sazonov A. M., Silyanov S. A., Bayukov O. A., Knyazev Yг. V., Zvyagina Y. A. et al. Composition and Ligand Microstructure of Arsenopyrite from Gold Ore Deposits of the Yenisei Ridge (Eastern Siberia, Russia). Minerals. 2019. Vol. 9, Iss. 12. 737. DOI: 10.3390/min9120737 9. Tauson V. L., Kravtsova R. G., Makshakov A. S., Lipko S. V., Arsentev K. Yu. Contrasting Surficial Composition of Native Gold from Two Different Types of Gold Ore Deposits. Minerals. 2017. Vol. 7, Iss. 8. 142. DOI: 10.3390/min7080142 10. Vasilevskiy B. B., Koneev R. I., Rustamov A. I., Turesebekov A. Kh., Ignatikov E. N. et al. New data on material constitution of Muruntau gold ore. Rudy i metally. 2004. No. 2. pp. 67–79. 11. Mironov A. G., Zhmodik S. M., Borovikov A. A., Damdinov B. B., Guntypov B. B. et al. The Kamennoe gold sulfide deposit (Northern Transbaikalia, Russia) as a representative of the riphean epithermal gold-telluride-silver ore mineralization. Geology of Ore Deposits. 2004. Vol. 46, No. 5. pp. 353–371. 12. Anjali Pal, Sujit Kumar Ghosh, Kunio Esumi, Tarasankar Pal. Reversible Generation of Gold Nanoparticle Aggregates with Changeable Interparticle Interactions by UV Photoactivation. Langmuir. 2004. Vol. 20, No. 3. pp. 575–578. 13. Zuohua Liu, Yan Li, Xiaoxia Zhou, Jun Du, Xing Fan et al. Research Progress of Electro-oxidation Intensification Leaching for Refractory Ore. Advanced Materials Research. 2011. Vol. 236-238. pp. 775–780. 14. Leonenko N. A., Kuzmenko A. P., Silyutin I. V., Kapustina G. G., Shvets N. L. Specifics of ultra disperse gold agglomeration under pulsed and continuous laser treatment. GIAB. 2009. Special issue 4. Far East-1. pp. 328–337. 15. Rubtsov Yu. I. Role of hydrogen ions in standard and activation heap leaching of gold. IOP Publishing IOP Conference Series: Earth and Environmental Science. 2017. Vol. 53. 012033. DOI: 10.1088/1755-1315/53/1/012033 16. Bryukhovetskiy O. S., Sekisov A. G., Lavrov A. Yu., Rasskazova A. V. Improvement of development efficiency in multi-component refractory gold ore fields using in-situ leaching. Gornyi Zhurnal. 2020. No. 2. pp. 66–69. DOI: 10.17580/gzh.2020.02.09 17. Sekisov A. G., Lavrov A. Yu., Shevchenko Yu. S., Manzyrev D. V., Konareva T. G. Geotechnology of extracting dispersed and “thin” gold from industrial minerals of Zabaikalsky krai. Vestnik ZabGU. 2012. No. 1(80). pp. 34–42. 18. Rasskazova A. V. Leaching of base gold-bearing ore with chloride-hypochlorite solutions. Proceedings of the XXIX International Mineral Processing Congress. Moscow, 2018. pp. 4093–4098. 19. Rasskazova A. V., Sekisov A. G., Kirilchuk A. G., Vasyanovich Yu. A. Stage-activation leaching of oxidized copper–gold ore: Theory and technology. Eurasian Mining. 2020. No. 1. pp. 52–55. DOI: 10.17580/em.2020.01.10 |