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High‐Pressure‐Field Induced Synthesis of Ultrafine‐Sized High‐Entropy Compounds with Excellent Sodium‐Ion Storage

Ming Liang, Haonan Xie, Biao Chen, Hongye Qin, Hanwen Zhang, Jingyi Wang, Junwei Sha, Liying Ma, Enzuo Liu, Jianli Kang, Chunsheng Shi, Fang He, Xiaopeng Han, Wenbin Hu, Naiqin Zhao, Chunnian He, Chunnian He

2024Angewandte Chemie International Edition40 citationsDOI

Abstract

Abstract Emerging high entropy compounds (HECs) have attracted huge attention in electrochemical energy‐related applications. The features of ultrafine size and carbon incorporation show great potential to boost the ion‐storage kinetics of HECs. However, they are rarely reported because high‐temperature calcination tends to result in larger crystallites, phase separation, and carbon reduction. Herein, using the NaCl self‐assembly template method, by introducing a high‐pressure field in the calcination process, the atom diffusion and phase separation are inhibited for the general formation of HECs, and the HEC aggregation is inhibited for obtaining ultrafine size. The general preparation of ultrafine‐sized (<10 nm) HECs (nitrides, oxides, sulfides, and phosphates) anchored on porous carbon composites is realized. They are demonstrated by combining advanced characterization technologies with theoretical computations. Ultrafine‐sized high entropy sulfides‐MnFeCoCuSnMo/porous carbon (HES‐MnFeCoCuSnMo/PC) as representative anodes exhibit excellent sodium‐ion storage kinetics and capacities (a high rating capacity of 278 mAh g −1 at 10 A g −1 for full cell and a high cycling capacity of 281 mAh g −1 at 20 A g −1 after 6000 cycles for half cell) due to the combining advantages of high entropy effect, ultrafine size, and PC incorporation. Our work provides a new opportunity for designing and fabricating ultrafine‐sized HECs.

Topics & Concepts

SodiumIonMaterials scienceHigh pressureChemical engineeringChemistryMetallurgyThermodynamicsOrganic chemistryPhysicsEngineeringFullerene Chemistry and ApplicationsDiamond and Carbon-based Materials ResearchLaser-Ablation Synthesis of Nanoparticles
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