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Ultrathin K–C Composite Anode Enables Conformal Stripping/Plating for Dendrite-Free and High-Rate Potassium-Metal Batteries

Zixing Wang, Jian‐Fang Wu, Wang Zhou, Ying Mo, Shi Chen, Tongyu Zhou, Wenzhuo Shen, Bohua Ren, Peifeng Huang, Jilei Liu

2024ACS Energy Letters26 citationsDOI

Abstract

The development of metallic K is seriously hampered by low melting point, high reactivity, and uncontrollable dendrite growth. Herein, benefiting from the super-potassiophility of CNTs (carbon nanotubes), K@CNT composite anodes are prepared via a rational fused-modeling approach, where CNTs build interconnected frameworks and K atoms are anchored on CNTs, inducing depressed atomic creeping and flowability at high temperatures. Thereby, K@CNT composite anodes deliver flexibility, processability (∼30 μm), and thermal stability (up to 300 °C). In particular, K@CNT composite anodes exhibit a conformal stripping and plating behavior along with the plane-structure of the CNT framework during charge–discharge processes under 10 mA cm –2 without dendrites. Moreover, the K@CNT // Prussian white full cells exhibit high rate performance (60.9 mAh g –1 at 3000 mA g –1 ), high energy density (187.3 Wh kg –1 ), and high-temperature stability. This work provides an avenue for designing high-performance metallic K anodes and for driving the commercialization of K-metal batteries.

Topics & Concepts

AnodeStripping (fiber)Plating (geology)Dendrite (mathematics)Composite numberPotassiumMaterials scienceMetalMetallurgyComposite materialChemistryElectrodeMathematicsPhysical chemistryGeophysicsGeologyGeometryAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesAdvanced battery technologies research
Ultrathin K–C Composite Anode Enables Conformal Stripping/Plating for Dendrite-Free and High-Rate Potassium-Metal Batteries | Litcius