Stable Na Deposition/Dissolution Enabled by 3D Bimetallic Carbon Fibers with Artificial Solid Electrolyte Interface
Sandro Schöner, Dana Schmidt, Leonie Wildersinn, Stephanie E. Wolf, Sebastian Speer, Beatrice Wolff, Arseniy Bokov, Pengfei Cao, Anna Windmüller, Xiaoxuan Chen, Chih‐Long Tsai, Fabian Jeschull, Hermann Tempel, Shicheng Yu, Rüdiger‐A. Eichel

TL;DR
This paper introduces a 3D bimetallic carbon fiber interlayer with an artificial SEI to enable stable sodium deposition and dissolution in sodium metal batteries.
Contribution
The novel approach combines bimetallic carbon fibers with a chemically presodiated artificial SEI to improve sodium battery performance.
Findings
The artificial SEI minimizes electrolyte decomposition and improves initial Coulombic efficiency.
The bimetallic CNF interlayer guides sodium deposition to prevent dendrite formation.
The system achieves over 99.5% average Coulombic efficiency for 600 cycles.
Abstract
3D bimetallic carbon nanofibers (CNFs) are promising interlayers for regulating Na deposition/dissolution on the Na metal or directly on current collectors like Cu. However, uncontrollable solid electrolyte interface (SEI) growth on the interlayer during the repeated Na plating/stripping process leads to low initial Coulombic efficiency (CE), impeding the practical applications of such a protective layer in Na metal batteries. Herein, an artificial SEI‐coated interlayer decorated with sodiophilic Ag and sodiophobic Cu on CNF is applied on Cu foil to regulate the Na deposition/dissolution behavior. The artificial SEI, consisting of organic components like RCO2Na/RCONa and inorganic reactants Na2CO3/NaxOy, minimizes irreversible electrolyte decomposition at the interlayer. The sodiophobic–sodiophilic bimetallic CNF interlayer is lightweight, porous, and mechanically robust. It can guide…
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Taxonomy
TopicsAdvancements in Battery Materials · Advanced Battery Materials and Technologies · Supercapacitor Materials and Fabrication
