Gold bearing pyrite leaching was conducted in H2SO4-Fe2(SO4)3 system at different reaction temperatures,with different ferric ion concentrations,sulfuric acid concentrations and stirring speeds.The leaching kinetics...Gold bearing pyrite leaching was conducted in H2SO4-Fe2(SO4)3 system at different reaction temperatures,with different ferric ion concentrations,sulfuric acid concentrations and stirring speeds.The leaching kinetics and mechanism were studied.When the temperature ranged between 30-75 °C,the pyrite leaching was mainly controlled by chemical reaction with positive correlation to the ferric ion concentration.The activation energy obtained from Arrhenius empirical formula is 51.39 k J/mol.The EDS and XPS analyses suggest that the oxidation of sulfur within pyrite is through a series of intermediate stages,and eventually is oxidized to sulphate accompanied with the formation of element sulfur.This indicates a thiosulfate oxidation pathway of the gold bearing pyrite oxidation in H2SO4-Fe2(SO4)3 system.展开更多
Three representative sulfide ore samples were collected from typical metal mines,and their corresponding pre-oxidized products were obtained under nature environment.The thermal behaviors of each sample at heating rat...Three representative sulfide ore samples were collected from typical metal mines,and their corresponding pre-oxidized products were obtained under nature environment.The thermal behaviors of each sample at heating rates of 5,10,15 and 20 °C/min in air flow from ambient temperature to 800 °C were studied by simultaneous thermal analysis and the TG/DSC curves before and after the pre-oxidation were compared.By the peak temperature of DTG curves,the whole reaction process for each sample was divided into different stages,and the apparent activation energies were calculated by the Ozawa-Flynn-Wall method.The results show that the reaction process of each sample after pre-oxidation is more complex,with quicker reaction rates,fewer heat production quantities,and higher or lower ignition-points.The apparent activation energies decrease from 364.017-474.228 kJ/mol to 244.523- 333.161 kJ/mol.Therefore,sulfide ores are more susceptible to spontaneous combustion after the pre-oxidation.展开更多
Molecular chain models of polyphenylene sulfide(PPS)with polymerization degrees ranging from 2 to 10 were constructed.The geometries of the models,representing various lengths of molecular chains,were optimized using ...Molecular chain models of polyphenylene sulfide(PPS)with polymerization degrees ranging from 2 to 10 were constructed.The geometries of the models,representing various lengths of molecular chains,were optimized using density functional theory.Subsequently,the activation energies and electronic properties of the reactions were computed.The findings indicated that the geometrical parameters of the PPS molecular chain model,with a polymerization degree exceeding 6,closely resemble actual PPS filters.Furthermore,the fluctuation in Mulliken charge of S atoms did not exceed 0.6%,and the variation in Mayer bond order was more consistent.The investigation revealed that the C-S bond and C-H bond are weaker links in the molecular chain,susceptible to disruption under harsh conditions.Analysis of the oxidation reaction between NO_(2)and PPS revealed the formation of a chemical bond between O atom in NO_(2)and S atom in PPS,emphasizing the influence of the electronic properties of PPS on the reaction.The activation energy for polyphenylene sulfide oxidation,with a polymerization degree greater than 6,remained constant at approximately 143 kJ·mol^(-1).Employing a molecular model of polyphenylene sulfide with a polymerization degree of 7 enhances the precision and reduces the computational workload in studying the oxidation reaction mechanism of PPS subjected to NO_(2).Selecting the appropriate length of the PPS molecular chain is crucial for investigating damage caused by flue gas components in PPS filter media and advancing filter media development further.展开更多
基金Project(51474075)supported by the National Natural Science Foundation of China
文摘Gold bearing pyrite leaching was conducted in H2SO4-Fe2(SO4)3 system at different reaction temperatures,with different ferric ion concentrations,sulfuric acid concentrations and stirring speeds.The leaching kinetics and mechanism were studied.When the temperature ranged between 30-75 °C,the pyrite leaching was mainly controlled by chemical reaction with positive correlation to the ferric ion concentration.The activation energy obtained from Arrhenius empirical formula is 51.39 k J/mol.The EDS and XPS analyses suggest that the oxidation of sulfur within pyrite is through a series of intermediate stages,and eventually is oxidized to sulphate accompanied with the formation of element sulfur.This indicates a thiosulfate oxidation pathway of the gold bearing pyrite oxidation in H2SO4-Fe2(SO4)3 system.
基金Project(51304051)supported by the National Natural Science Foundation of ChinaProject(2012J05088)supported by the Natural Science Foundation of Fujian Province,China+1 种基金Project(022409)supported by School Talent Award of Fuzhou University,ChinaProject(2013-XQ-18)supported by Science&Technology Development Foundation of Fuzhou University,China
文摘Three representative sulfide ore samples were collected from typical metal mines,and their corresponding pre-oxidized products were obtained under nature environment.The thermal behaviors of each sample at heating rates of 5,10,15 and 20 °C/min in air flow from ambient temperature to 800 °C were studied by simultaneous thermal analysis and the TG/DSC curves before and after the pre-oxidation were compared.By the peak temperature of DTG curves,the whole reaction process for each sample was divided into different stages,and the apparent activation energies were calculated by the Ozawa-Flynn-Wall method.The results show that the reaction process of each sample after pre-oxidation is more complex,with quicker reaction rates,fewer heat production quantities,and higher or lower ignition-points.The apparent activation energies decrease from 364.017-474.228 kJ/mol to 244.523- 333.161 kJ/mol.Therefore,sulfide ores are more susceptible to spontaneous combustion after the pre-oxidation.
基金supported by the China National Key R&D Program during the 13~(th)Five-year Plan Period(2018YFC0705300)the Fundamental Research Funds for the Central Universities(2232017A-09)
文摘Molecular chain models of polyphenylene sulfide(PPS)with polymerization degrees ranging from 2 to 10 were constructed.The geometries of the models,representing various lengths of molecular chains,were optimized using density functional theory.Subsequently,the activation energies and electronic properties of the reactions were computed.The findings indicated that the geometrical parameters of the PPS molecular chain model,with a polymerization degree exceeding 6,closely resemble actual PPS filters.Furthermore,the fluctuation in Mulliken charge of S atoms did not exceed 0.6%,and the variation in Mayer bond order was more consistent.The investigation revealed that the C-S bond and C-H bond are weaker links in the molecular chain,susceptible to disruption under harsh conditions.Analysis of the oxidation reaction between NO_(2)and PPS revealed the formation of a chemical bond between O atom in NO_(2)and S atom in PPS,emphasizing the influence of the electronic properties of PPS on the reaction.The activation energy for polyphenylene sulfide oxidation,with a polymerization degree greater than 6,remained constant at approximately 143 kJ·mol^(-1).Employing a molecular model of polyphenylene sulfide with a polymerization degree of 7 enhances the precision and reduces the computational workload in studying the oxidation reaction mechanism of PPS subjected to NO_(2).Selecting the appropriate length of the PPS molecular chain is crucial for investigating damage caused by flue gas components in PPS filter media and advancing filter media development further.
