Transformation pathway of excluded mineral pyrite decomposition in CO2 atmosphere

Transformation pathway of excluded mineral pyrite decomposition in CO2 atmosphere

Pyrite (FeS2) is one of the major contributors to slagging during coal utilization procedure; however, the evolution of FeS2 is a complex process under different conditions. The transformation behaviors of FeS2 in CO2 under different experimental conditions were studied by characterizing the solid a...

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Bibliographic Details
Published in:Fuel processing technology Vol. 138; pp. 814 - 824
Main Authors: Huang, Fang, Zhang, Li-Qi, Yi, Bao-Jun, Xia, Zuo-Jun, Zheng, Chu-Guang
Format: Journal Article
Language:English
Published: Elsevier B.V 01-10-2015
Subjects:
Carbon dioxide
Eutectic molten phase
Iron oxides
Pyrite transformation
Eutectic molten phase
Iron oxides
Carbon dioxide
Pyrite transformation
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Summary:Pyrite (FeS2) is one of the major contributors to slagging during coal utilization procedure; however, the evolution of FeS2 is a complex process under different conditions. The transformation behaviors of FeS2 in CO2 under different experimental conditions were studied by characterizing the solid and gas products. Mössbauer spectroscopy was used to identify the Fe-containing phase. The results showed that the FeS2 begins to decompose at 560°C, and all decomposition processes are endothermic in CO2 atmosphere. When the temperature is <700°C, pyrrhotite (FeSx, 1≤x<2) is the only solid product during FeS2 thermal decomposition in CO2 atmospheres. However, at the reactor temperature ≥700°C, magnetite (Fe3O4) and FeSx are the primary solid products. The FeO–FeS (i.e., iron oxy-sulfide droplets) molten system begins to appear at a reactor temperature of 950°C, and the eutectic FeO–FeS phase becomes the major phase at the temperatures above 1000°C. High CO2 concentrations may promote the FeS2 to form Fe3O4, CO and SO2. The solid products (e.g., Fe3O4) may be further oxidized to form hematite (Fe2O3) after the FeS2 was heated for a longer time; this would be, mainly due to CO2 reacting with FeS2 thermal decomposition product Fe3O4. A transformation pathway of FeS2 decomposition in CO2 atmosphere was thus defined. [Display omitted] •Pyrite thermal decomposition occurs at about 560°C in CO2 atmosphere.•Melting phase starts to form at about 950°C in CO2 atmosphere.•Higher CO2 concentration promotes the transformation of the pyrrhotite into iron oxides.•A transformation mechanism of pyrite decomposition is proposed in CO2 atmosphere.
ISSN:0378-3820
1873-7188
DOI:10.1016/j.fuproc.2015.07.028