Author:
Niu 钮 Wei 伟,Song 宋 Qin-Xin 沁心,Chang 常 Shi-Qi 世琦,Wang 王 Min 敏,Yuan 袁 Kui 奎,Gao 高 Jia-Cheng 嘉程,Wang 王 Shuo 硕,Wang 王 Zhen-Dong 振东,Liu 刘 Kai-Fei 凯斐,Liu 刘 Ping 萍,Xu 徐 Yong-Bing 永兵,Zhang 张 Xiao-Qian 晓倩,Pu 普 Yong 勇
Abstract
Abstract
The self-intercalation of Cr into pristine two-dimensional (2D) van der Waals ferromagnetic CrTe2, which forms chromium tellurides (Cr
x
Te2), has garnered interest due to their remarkable magnetic characteristics and the wide variety of chemical compositions available. Here, comprehensive basic characterization and magnetic studies are conducted on quasi-2D ferromagnetic Cr1.04Te2 crystals. Measurements of the isothermal magnetization curves are conducted around the critical temperature to systematically investigate the critical behavior. Specifically, the critical exponents β = 0.2399, γ = 0.859, and δ = 4.3498, as well as the Curie temperature T
C = 249.56 K, are determined using various methods, including the modified Arrott plots, the Kouvel–Fisher method, the Widom scaling method, and the critical isotherm analysis. These results indicate that the tricritical mean-field model accurately represents the critical behavior of Cr1.04Te2. A magnetic phase diagram with tricritical phenomenon is thus constructed. Further investigations confirm that the critical exponents obtained conform to the scalar equation near T
C, indicating their self-consistency and reliability. Our work sheds light on the magnetic properties of quasi-2D Cr1.04Te2, broadening the scope of the van der Waals crystals for developments of future spintronic devices operable at room temperature.