[Oral Presentation]Synthesis of porous carbon/minerals interwoven electrocatalysts from coal gasification fine slag for synergistic treatment of phenolic wastewater
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[Oral Presentation]Synthesis of porous carbon/minerals interwoven electrocatalysts from coal gasification fine slag for synergistic treatment of phenolic wastewater

Synthesis of porous carbon/minerals interwoven electrocatalysts from coal gasification fine slag for synergistic treatment of phenolic wastewater
ID:328 Submission ID:18 View Protection:ATTENDEE Updated Time:2024-05-16 20:09:45 Hits:488 Oral Presentation

Start Time:2024-05-31 17:00 (Asia/Shanghai)

Duration:15min

Session:[S6] Clean Processing, Conversion and Utilization of Energy Resources » [S6-2] Afternoon of May 31st

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Abstract
    Coal gasification fine slag (GFS), a difficult-to-dispose solid waste in the coal chemical industry, consists of minerals and residual carbon, which has great potential for resource utilization. However, due to the aggregate structure of minerals and its complex embedding patterns in the carbon matrix, the high-value utilization of GFS remains challenging. Based on the intrinsic characteristics of GFS, this study synthesized various porous carbon/minerals interwoven electrocatalysts for electrochemical oxidation of phenolic wastewater. Meanwhile, minerals were utilized to regulate the surface chemical and pore structure of electrocatalysts, turning disadvantages of minerals into advantages, which caused a sharp increase in wastewater treatment capacity. The positive effect of minerals on electrocatalyst properties was investigated by characterization techniques, electrochemical analyses and DFT calculations. It was found that silicate mediated iron conversion through strong interaction with H2O2, high work function gradient with electroactive iron, and excellent •O2- production capacity improved the reversibility and kinetics of the entire electrocatalytic reaction. Within the electrocatalytic system, the m-cresol removal rate reached 99.55±1.24%, surpassing most reported electrocatalysts. The adsorption and electrooxidation experiment confirmed that the carbon exhibited a hierarchical porous structure, facilitating the entry of H2O2 into the catalytic sites of minerals. Abundant catalytic sites in minerals accelerated adsorption and oxidation processes on carbon surfaces. More importantly, the synergy of carbon and minerals effectively shortened the diffusion path of short-lived radicals to degrade phenolic wastewater. Hence, this research provides new insights into the problem of mineral limitations and opens an innovative approach for GFS recycling and environmental remediation.
Keywords
gasification fine slag,phenolic wastewater,composite electrocatalyst,electrochemical advanced oxidation,synergistic effect
Speaker
Yanjie Niu
China University of Mining and Technology

Submission Author
Yanjie Niu China University of Mining and Technology
Jianjun Wu China University of Mining and Technology
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