Issue 3, 2023

A high-energy aqueous Zn‖NO2 electrochemical cell: a new strategy for NO2 fixation and electric power generation

Abstract

Air pollution by nitrogen oxides (NO2) from exhaust gas is a deep-seated problem, thus urgently calling for new capture and abatement technologies. Meanwhile, the electrocatalytic conversion of NO2 to value-added chemicals is a promising strategy for mitigating human-caused imbalances of the global nitrogen cycle. Here, we propose an electrochemical cell based on an aqueous Zn‖NO2 system with a nano-NiO catalyst deposited as the cathode, a metallic Zn foil as the anode and a ZnCl2 aqueous solution as the electrolyte. Importantly, the electrolyte can efficiently capture NO2, then convert it to NO2 and eventually to value-added NH3, while simultaneously producing electric power. As proof of concept, a battery has been fabricated, which exhibits bifunctional activity and stability (>100 h) towards reversible NO2 reduction and evolution reactions. A high cell-level energy density of 553.2 W h kg−1cell/1589.6 W h L−1cell from pouch cells (2.4 Ah) has been achieved. As an additional green feature, the produced NO2 by the Zn‖NO2 cell is subsequently converted to NH3 by a self-powered mechanism, thereby servicing multiple key conversion steps in the nitrogen cycle all within a single device, paving the way to scalable, highly integrated solutions.

Graphical abstract: A high-energy aqueous Zn‖NO2 electrochemical cell: a new strategy for NO2 fixation and electric power generation

Supplementary files

Article information

Article type
Paper
Submitted
21 Nov 2022
Accepted
23 Jan 2023
First published
24 Jan 2023
This article is Open Access
Creative Commons BY license

Energy Environ. Sci., 2023,16, 1125-1134

A high-energy aqueous Zn‖NO2 electrochemical cell: a new strategy for NO2 fixation and electric power generation

L. Ma, S. Chen, W. Yan, G. Zhang, Y. Ying, H. Huang, D. Ho, W. Huang and C. Zhi, Energy Environ. Sci., 2023, 16, 1125 DOI: 10.1039/D2EE03749A

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