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Efficient atomically dispersed Fe catalysts with robust three-phase interface for stable seawater-based zinc-air batteries

Daokun Kang, Canhui Zhang, Xingkun Wang, Fanqi Wang, Huiyu Gai, Hanxu Yao, Xu Liu, Zhuangzhuang He, Minghua Huang, Heqing Jiang

2024Green Carbon29 citationsDOIOpen Access PDF

Abstract

The use of seawater-based electrolytes in zinc-air batteries (S-ZABs) presents significant economic and social benefits and mitigates the demand for scarce freshwater resources. However, it is challenging to achieve a metal–nitrogen–carbon (M–N–C) catalyst that exhibits high resistance to corrosive Cl – in seawater-based electrolytes and possesses a strengthened binding affinity with O 2 , which enables catalysts with an optimized oxygen reduction reaction (ORR) and enhances the applicability of S-ZABs. Herein, we propose a combined wet chemistry-pyrolysis strategy to obtain atomically dispersed Fe-decorated nitrogen-doped mesoporous carbon spheres (N-MCS-Fe-900). Benefiting from the capacity of the Fe decorations to form the edge-hosted aerophilic FeN 4 -O 2 sites at the optimized three-phase interface, N-MCS-Fe-900 affords the enhanced resistance of the active Fe sites to corrosive Cl – , as well as improved interaction with O 2 , thereby facilitating the ORR process. As expected, the N-MCS-Fe-900 delivers high half wave potential of 0.90 V and kinetic current density of 18.61 mA cm −2 at 0.85 V in seawater-based 0.1 M KOH. More importantly, the S-ZABs equipped with N-MCS-Fe-900 exhibited long-term stability under a high current density for over 140 h without voltage decay. Theoretical calculations and electrochemical performance evaluations collectively revealed the superior catalytic efficacy and genesis of this activity in N-MCS-Fe-900, which features edge-hosted FeN 4 -O 2 sites at the stable three-phase interface in seawater electrolytes. This study provides new insights for the advancement of ORR catalysts in sustainable energy conversion technologies for seawater-based electrolytes. This work proposes a strategy to construct the edge-hosted aerophilic FeN 4 -O 2 sites at the optimized three-phase interface, N-MCS-Fe-900 affords the enhanced resistance of the active Fe sites to corrosive Cl - , as well as improved interaction with O 2 , thereby facilitating the ORR process and hitting the spot of long-term stability under high current density over 140 h for seawater-based ZABs.

Topics & Concepts

SeawaterZincCatalysisMaterials sciencePhase (matter)Interface (matter)Chemical engineeringMetallurgyComposite materialChemistryEngineeringGeologyOceanographyOrganic chemistryWettingSessile drop techniqueElectrocatalysts for Energy ConversionAdvanced battery technologies researchAdvancements in Battery Materials
Efficient atomically dispersed Fe catalysts with robust three-phase interface for stable seawater-based zinc-air batteries | Litcius