Chemistry that saves. The transformation of cyanide in modern mining
Keywords:
Detoxification, Cyanide, Hydrogen peroxide, Catalysis, Optimization.Synopsis
In an industrial mining effluent treatment plant, the detoxification process of cyanide solutions was studied using hydrogen peroxide at two different concentrations. The objective was to analyze how the degradation rate of free cyanide varied under controlled pH conditions and in the presence of copper as a catalyst. Two tank systems were compared in parallel, measuring the decrease of cyanide over time until its conversion into less toxic compounds. The results showed that the higher concentration of peroxide significantly accelerated the reaction, achieving a more efficient degradation with a lower consumption of reagents. This finding allowed optimizing the process, reducing costs without compromising the effectiveness of the treatment. The study confirmed that, under the right conditions, it is possible to neutralize cyanide in a reliable and sustainable manner, providing practical solutions for the mining industry.
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References
Amaouche, H., Chergui, S., Halet, F., Yeddou, A. R., Chergui, A., Nadjemi, B., Ould-Dris, A. (2019). Removal of cyanide in aqueous solution by oxidation with hydrogen peroxide catalyzed by copper oxide. Water Sci Technol, 80(1), 126-133. https://doi.org/10.2166/wst.2019.254
Ahsan, Q., Griffiths, A., Haug, E., y Norcross, R. (1990). Process for the removal of cyanide from wastewaters (Patent Núm. 4966715). En US Patent (Núm. 4966715). https://patents.google.com/patent/US4966715A/en
Aranguri LLerena, G., y Reyes López, I. A. (2018). Cyanide degradation from mining effluent using two reagents: Sodium metabisulphite and the metabisulphite mixture with hydrogen peroxide. TECCIENCIA, 13(25), 1–9. https://doi.org/10.18180/tecciencia.2018.25.1
Baharun, N., Ling, O. P., Rezaei Ardani, M., Ariffin, K. S., Yaraghi, A., Abdullah, N. S., Putra, T. A. R., y Ismail, S. (2020). Effect of hydrogen peroxide and lead (II) nitrate on gold cyanide leaching of Malaysian mesothermal deposit gold ore. Physicochemical Problems of Mineral Processing, 56(5), 905–918. https://doi.org/10.37190/ppmp/126629
Barrientos Lezcano, J.C. (2018). Estudio de la reacción de oxidación química de cianuro para el tratamiento de aguas residuales de una empresa minera [Trabajo de grado, Universidad EAFIT].
Box, G., Hunter, S., y Hunter, W. (2008). Estadística para Investigadores, Diseño, innovación y descubrimiento. Editorial Reverte edición Barcelona.
Carranza, R., y Lozano, D. (2013). Influencia del Peróxido de Hidrogeno sobre la degradación de Cianuro, del Cloruro Férrico durante la precipitación del arsénico del sulfhidrato de sodio durante la precipitación del mercurio, presentes en la planta de tratamiento de efluentes de la compañía minera Coimolache S.A. [Tesis de pregrado, Universidad Nacional de Trujillo].
Díaz, D., y Condori, I. (2009). Proceso de detoxificación de soluciones cianuradas, usando el método INCO en efluentes mineros [Tesis de pregrado, Universidad Nacional de Ingeniería].
Dong, K., Xie, F., Wang, W., Chang, Y., Lu, D., Gu, X., y Chen, C. (2021). The detoxification and utilization of cyanide tailings: A critical review. Journal of Cleaner Production, 302(126946). https://doi.org/10.1016/j.jclepro.2021.126946
Estrada-Montoya, C. C., Restrepo Franco, G. M., y Galeano Vanegas, N. F. (2020). Evaluation of cyanide and heavy metals removal in liquid effluents from small mining’s gold benefit, by adsorption with activated carbon and hydrogen peroxide in Segovia, Antioquia. Dyna, 87(212), 9–17. https://doi.org/10.15446/dyna.v87n212.79716
Fernandez Essenwanger, G. R., & Moreno Eustaquio, W. (2023). Influencia de la concentración de peróxido de hidrógeno en la detoxificación de relaves mineros cianurados. Revista CIENCIA Y TECNOLOGÍA, 19(2), 27-36. https://doi.org/10.17268/rev.cyt.2023.02.02
Fernández, G. (2015). Concentraciones de cobre y su efecto en los niveles de cianuro libre de las soluciones cianuradas por detoxificación [Tesis de Maestría, Universidad Nacional de Trujillo].
Griffiths, A. D., Dr. Ahsan, Q. M., Norcross, R., Knorre, H. D., y Merz, F. W. (1992). Process for the treatment of effluents containing cyanide and/or other oxidizable substances (Patent Núm. 0355417: B1). European Patent.
Griffiths, A., Knorre, H., Gos, S. y Higgins, R. (1987). The detoxification of gold-mill tailings with hydrogen peroxide. Journal of the Southern African Institute of Mining and Metallurgy, 87(9), 279- 283.
Hou, D., Liu, L., Yang, Q., Zhang, B., Qiu, H., Ruan, S., Chen, Y., y Li, H. (2020). Decomposition of cyanide from gold leaching tailingsby using sodium metabisulphite and hydrogen peroxide. Wiley. https://doi.org/10.1155/2020/5640963
Evonik (2022, 06 de diciembre). Hydrogen peroxide for mining. Evonik.com. https://lc.cx/h5eNtl
Kitis, M., Akcil, A., Karakaya, E., y Yigit, N. O. (2005). Destruction of cyanide by hydrogen peroxide in tailings slurries from low bearing sulphidic gold ores. Minerals Engineering, 18(3), 353–362. https://doi.org/10.1016/j.mineng.2004.06.003
Krylova, L. N., Seliverstov, A. F., y Ryabtsev, D. A. (2021). Cleaning of industrial waters containing cyanides by using a combination of ozone and hydrogen peroxide. Metallurgist (USSR), 64(11–12), 1331–1339. https://doi.org/10.1007/s11015-021-01123-y
Labat, L., Dumestre-Toulet, V., Goullé, J. P., y Lhermitte, M. (2004). A fatal case of mercuric cyanide poisoning. Forensic Science International, 143(2–3), 215–217. https://doi.org/10.1016/j.forsciint.2004.02.039
Montgomery, D. (2005). Diseño y análisis de experimentos. Limusa Wiley.
Mamani Endara, O. A. (2007) Implementación de Procesos de destrucción de Cianuro con Sulfato Ferroso y Peróxido de Hidrógeno. Universidad Nacional de Ingeniería.
Marsden, J., y House, E. (2006). The Chemistry of Gold Extraction. Editorial SME.
Mas, M., Aguirre, F., Amaya, G., Torres, F., y Marchevsky, N. (2009). Procesos de destrucción de complejos cianurados. Universidad Nacional del Cuyo.
Muboko, N., Muposhi, V., Tarakini, T., Gandiwa, E., Vengasayi, S., y Makuwe, E. (2014). Cyanide poisoning and African elephant mortality in Hwange National Park, Zimbabwe: A preliminary assessment. Pachyderm, 55, 92–94.
Ngulube, M. (2016). Elimination cyanide with hydrogen peroxide (H2O2) and calcium hypochlorite (ca(OCl)2) on Gold Mine waste from north luwu, south Sulawesi. American Journal of Environmental Protection, 5(4), 97. https://doi.org/10.11648/j.ajep.20160504.14
Pérez, B. F. (2007). Desarrollo de un nuevo método para la eliminación de cianuro de aguas residuales de mina. Universidad de Oviedo.
Rai, A., Chakrabarty, J., y Dutta, S. (2021). Phycoremediation of pollutants from coke-oven wastewater using Tetraspora sp. NITD 18 and estimation of macromolecules from spent biomass. Journal of Water Process Engineering, 39(101746). https://doi.org/10.1016/j.jwpe.2020.101746
Rapid Response Assessment, A. (s/f). Mine tailings storage: Safety is no accident. Amazonaws.com. https://lc.cx/sc4M86
Razali, N. M., y Wah, Y. B. (2011). Power comparisons of Shapiro-Wilk, Kolmogorov-Smirnov, Lilliefors and Anderson-Darling tests. https://lc.cx/T9sGT3
Roche, C., Thygesen, K., Baker, E. (2017). Mine Tailings Storage: Safety Is No Accident. A UNEP Rapid Response Assessment. United Nations Environment Programme and GRID-Arendal, Nairobi and Arendal.
Sanyaolu, N. O., Ibikunle, A. A., Kareem, F. A., Ogunmoye, A. O., Ogundare, S. A., Atewolara-Odule, O. C., Hashim, A. M., Akinwunmi, F., Adewuyi, S., Shittu, T., Eromosele, C. O., y Torto, N. (2021). Catalytic detoxification of aqueous cyanide using copper crown electrospun chitosan nanofiber. Journal of Chemical Society of Nigeria, 46(2). https://doi.org/10.46602/jcsn.v46i2.615
Syahrul, S., Rumiko, K., Akiko, T., Tantut, S., Ruka, S., Fithria, A. (2016). Prevalence of underweight and overweight among school-aged children and it’s association with children’s sociodemographic and lifestyle in Indonesia. International Journal of Nursing Sciences, 3(2), 169-167. https://doi.org/10.1016/j.ijnss.2016.04.004
Pesántez, D., De La Torre, E., y Guevara, A. (2010). Influencia del ion cúprico y del cobre metálico en la oxidación del cianuro libre con aire y carbón activado. Revista Politécnica. 29(1), 1-7.
Tu, Y., Han, P., Wei, L., Zhang, X., Yu, B., Qian, P., y Ye, S. (2019). Removal of cyanide adsorbed on pyrite by H2O2 oxidation under alkaline conditions. Journal of Environmental Sciences (China), 78, 287–292. https://doi.org/10.1016/j.jes.2018.10.013
Tyagi, M., Rana, A., Kumari, S., y Jagadevan, S. (2018). Adsorptive removal of cyanide from coke oven wastewater onto zero-valent iron: Optimization through response surface methodology, isotherm and kinetic studies. Journal of Cleaner Production, 178, 398–407. https://doi.org/10.1016/j.jclepro.2018.01.016
Uppal, H., Tripathy, S. S., Chawla, S., Sharma, B., Dalai, M. K., Singh, S. P., Singh, S., y Singh, N. (2017). Study of cyanide removal from contaminated water using zinc peroxide nanomaterial. Journal of Environmental Sciences (China), 55, 76–85. https://doi.org/10.1016/j.jes.2016.07.011
Published
April 7, 2025
Series
Copyright (c) 2025 Gustavo Raúl Fernández Essenwanger, Emérito Gustavo Fernández Essenwanger, Gustavo Paul Fernández Chávez, Antonio Manuel Otoya Zelada, Walter Moreno Eustaquio, Marcelino Torres Villanueva
Details about the available publication format: PDF
PDF
ISBN-13 (15)
978-9942-561-13-8
Publication date (01)
2025-04-07
