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Joule Heating Driven Graphitization Regulation and Ni Single‐Atom Modification in Hard Carbon for Low‐Voltage and High‐Rate Potassium‐Ion Storage

Lei Yang, Huaipeng Pang, Wancheng Ren, Xinyu Wang, Yuchen Wei, Pengfei Lu, Jingwei Chen, Weiqian Tian, Minghua Huang, Huanlei Wang

2025Advanced Functional Materials11 citationsDOI

Abstract

Abstract Hard carbon (HC), a promising anode for potassium‐ion hybrid capacitors (PIHCs), must deal with the tradeoff between low‐voltage (≤1 V) charging capacity and rate capability, which are two important but mutually restrictive properties. Herein, a Joule heating coupled with a metal salt catalysis strategy is reported to rapidly construct Ni single‐atom modified N‐doped HC (NiNHC−J) with controllable graphitization. The metal salt acts both as a single‐atom dopant and a graphitization catalyst, with Joule heating temperature optimization enabling precise control over graphitization degree. Furthermore, the Joule heating drives Ni single‐atom content up to 2.29 wt.%, which can induce a local electric field to accelerate electron/ion transportation and meanwhile promote electrolyte decomposition to form an ultrathin and KF‐enriched solid‐electrolyte interphase. Consequently, the optimized NiNHC−J delivers extraordinary low‐voltage charging capacity (290 mAh g −1 at 0.1 A g −1 ), excellent rate capability (144 mAh g −1 at 10 A g −1 ), and outstanding cycling stability for 2000 cycles (capacity decay < 0.0145% per cycle). Impressively, the as‐assembled PIHC based on NiNHC−J anode achieves impressive energy/power densities (122 Wh kg −1 /16 167 W kg −1 ). This work establishes an innovative strategy combined with graphitization regulation and metal single‐atom modification, offering fundamental insights in the HC anode with low‐voltage and high‐rate potassium‐ion storage.

Topics & Concepts

Materials sciencePotassiumIonCarbon fibersJoule (programming language)Atom (system on chip)VoltageJoule heatingNanotechnologyMetallurgyThermodynamicsComposite materialElectrical engineeringOrganic chemistryComposite numberComputer sciencePhysicsChemistryEngineeringEmbedded systemPower (physics)Advancements in Battery MaterialsSupercapacitor Materials and FabricationAdvanced Battery Materials and Technologies