Catalytic reduction of nitrogen monoxide using iron–nickel oxygen carriers derived from electroplating sludge: Novel method for the collaborative emission decrease of polluting gases

The valorization of electroplating sludge (ES) for high added value presents greater economic and environmental benefits than conventional treatment methods such as thermal processing, solidification, and landfill. Inspired by the mechanism of chemical looping combustion (CLC), this study developed...

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Bibliographic Details
Published in:The Science of the total environment 2024-06, Vol.927, p.172315-172315, Article 172315
Main Authors: Wang, Xuchao, Ding, Chengyi, Long, Hongming, Wu, Yuxi, Zhao, Hexi, Jiang, Feng, Chang, Rende, Xue, Sheng, Shen, Mingrui, Yang, Xin
Format: Article
Language:English
Subjects:
Catalyst
Electroplating sludge
NiFe2O4
Oxygen carriers
Resource utilization
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Summary:The valorization of electroplating sludge (ES) for high added value presents greater economic and environmental benefits than conventional treatment methods such as thermal processing, solidification, and landfill. Inspired by the mechanism of chemical looping combustion (CLC), this study developed a novel cost-effective method for denitrification by preparing FeNi-OCs from ES to achieve the synergistic reduction of CO and NO emissions. The phase structure, micromorphology, and valence state changes of the FeNi-OC catalyst during the CO-catalyzed reduction of NO and the pathway for catalytic denitrification using FeNi-OCs were analyzed. Results showed that CO could reduce FeNi-OCs to FeNi, and the reduced FeNi was subsequently oxidized back to FeNi-OCs by NO, a process analogous to CLC. During experiments, the simultaneous consumption of CO and NO gases was observed at 350 °C. This phenomenon was highly pronounced at 600 °C, where the CO and NO concentrations decreased from initial values of 8550 and 470 ppm, respectively, to 6719 and 0 ppm, respectively, with conversion rates of 21.41 % and 100 %, respectively. Hence, synergistic emission reduction was achieved. Further experiments also indicated that the addition of 1.5 % ES during iron ore sintering could substantially reduce the CO and NO concentrations in the sintering flue gas from 1268.32 and 244.81 ppm, respectively, to 974.51 and 161.11 ppm, respectively. [Display omitted] •The catalyst derived from electroplating sludge demonstrated effective catalysis for the reduction of NO by CO.•The reaction pathways of the catalyst during the catalytic process were elucidated.•The conversion of NO can reach 100 % under the synergistic effect of CO gases.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2024.172315