Dense binary Fe-Cu sites promoting CO utilization enable highly reversible hybrid Na-CO batteries

High-performance and low-cost catalysts are particularly desirable for the exploitation of practical low-overpotential Na-CO 2 batteries with protracted cyclability. Herein, a well-defined morphology of nitrogen-rich graphitic carbon frameworks with dense bimetallic active sites (Fe-Cu-N-C) was faci...

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Published in:Journal of materials chemistry. A, Materials for energy and sustainability Materials for energy and sustainability, 2021-10, Vol.9 (38), p.22114-22128
Main Authors: Xu, Changfan, Zhan, Jing, Wang, Huanwei, Kang, Yao, Liang, Feng
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Summary:High-performance and low-cost catalysts are particularly desirable for the exploitation of practical low-overpotential Na-CO 2 batteries with protracted cyclability. Herein, a well-defined morphology of nitrogen-rich graphitic carbon frameworks with dense bimetallic active sites (Fe-Cu-N-C) was facilely prepared by introducing Fe 3+ and Cu 2+ to regulate in situ grown carbon nanotubes as an advanced catalyst toward hybrid Na-CO 2 batteries. Through metal content tuning and carbon architecture altering, Fe-Cu-N-C proved to be dramatically more effective than Cu-N-C and Fe-N-C. As the cathodic catalyst of a hybrid Na-CO 2 battery, Fe-Cu-N-C can facilitate the fast evolution and degradation of flocculent discharge products and achieve an excellent long-term cyclability with up to 1550 cycles (over 600 h), which makes it one of the greatest catalysts for hybrid Na-CO 2 /air batteries that have been reported to date. The observed outstanding battery performance is attributable to the cross-linked conductive framework affording a "highway" for accelerated electron transport and Na + /CO 2 diffusion. Besides, the synergistic effects among defect-rich interfaces, Fe/Fe 3 C nanocrystals, and Fe-N x and Cu-N x sites derived from nitrogen atom doping enhance the catalytic activity. In addition, the possible growth and decomposition mechanisms of NaHCO 3 products with different morphologies on Fe-N-C, Cu-N-C, and Fe-Cu-N-C electrodes were presented and discussed. Dense binary Fe-Cu sites promoting CO 2 utilization enable ultra-low-voltage gap and ultra-long life hybrid Na-CO 2 batteries.
ISSN:2050-7488
2050-7496
DOI:10.1039/d1ta06611k