High-Entropy Magnet Enabling Distinctive Thermal Expansions in Intermetallic Compounds
Jinghan Li, Kun Lin, Hankun Xu, Wanda Yang, Qian Zhang, Chengyi Yu, Qinghua Zhang, Jing Chen, Chin-Wei Wang, Kenichi Kato, Shogo Kawaguchi, Youyong Li, Yili Cao, Qiang Li, Xin Chen, Jun Miao, Jinxia Deng, Xianran Xing
Abstract
The high-entropy strategy has gained increasing popularity in the design of functional materials due to its four core effects. In this study, we introduce the concept of a “high-entropy magnet (HEM)”, which integrates diverse magnetic compounds within a single phase and is anticipated to demonstrate unique magnetism-related properties beyond that of its individual components. This concept is exemplified in AB 2 -type layered Kagome intermetallic compounds (Ti,Zr,Hf,Nb,Fe)Fe 2 . It is revealed that the competition among individual magnetic states and the presence of magnetic Fe in originally nonmagnetic high-entropy sites lead to intricate magnetic transitions with temperature. Consequently, unusual transformations in thermal expansion property (from positive to zero, negative, and back to near zero) are observed. Specifically, a near-zero thermal expansion is achieved over a wide temperature range (10–360 K, α v = −0.62 × 10 –6 K –1 ) in the A-site equal-atomic ratio (Ti 1/5 Zr 1/5 Hf 1/5 Nb 1/5 Fe 1/5 )Fe 2 compound, which is associated with successive deflection of average Fe moments. The HEM strategy holds promise for discovering new functionalities in solid materials.