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High‐Entropy Carbonitride MAX Phases and Their Derivative MXenes

Zhiguo Du, Cheng–Chia Wu, Yu‐Chuan Chen, Qi Zhu, Yanglansen Cui, Haiyang Wang, Yongzheng Zhang, Xiao Chen, Jiaxiang Shang, Bin Li, Weihua Chen, Chuntai Liu, Shubin Yang

2021Advanced Energy Materials192 citationsDOI

Abstract

Abstract Although high‐entropy layered transition metal carbonitride MAX phases and their derivative MXenes have been proposed to exhibit unique physicochemical features for widespread applications, it is still challenging to synthesize them owing to the easy formation of separated phases during the traditional synthetic process. Here, a new high‐entropy carbonitride MAX phase (HE CN‐MAX, (Ti 1/3 V 1/6 Zr 1/6 Nb 1/6 Ta 1/6 ) 2 AlC x N 1–x ) is synthesized on the basis of metallurgically treating medium‐entropy MAX (ME‐MAX) (Zr 1/3 Nb 1/3 Ta 1/3 ) 2 AlC and other MAX phases (Ti 4 AlN 3 and V 2 AlC). During the metallurgical process, the unique usage of a medium‐entropy MAX phase effectively solves the phase separation issue for the formation of a high‐entropy MAX phase owing to their low entropy difference. After selective extraction of an A species, a high‐entropy carbonitride MXene (HE CN‐MXene) with high mechanical strains and five types of metal‐nitrogen bonds is achieved, which shows good adsorption and catalytic activities for lithium polysulfides. As a result, a lithium–sulfur battery with HE CN‐MXene delivers a high‐rate capability (702 mAh g −1 at 4 C) and good cycling stability.

Topics & Concepts

MXenesMaterials scienceEntropy (arrow of time)CarbideAdsorptionThermodynamicsNanotechnologyPhysical chemistryMetallurgyChemistryPhysicsMXene and MAX Phase Materials2D Materials and ApplicationsAdvanced Photocatalysis Techniques
High‐Entropy Carbonitride MAX Phases and Their Derivative MXenes | Litcius