Qian Kai, Gao Lei, Chen Xiya, Li Hang, Zhang Shuai, Zhang Xian-Li, Zhu Shiyu, Yan Jiahao, Bao Deliang, Cao Lu, Shi Jin-An, Lu Jianchen, Liu Chen, Wang Jiaou, Qian Tian, Ding Hong, Gu Lin, Zhou Wu, Zhang Yu-Yang, Lin Xiao, Du Shixuan, Ouyang Min, Pantelides Sokrates T, Gao Hong-Jun
Institute of Physics and University of Chinese Academy of Sciences, Chinese Academy of Sciences, Beijing, 100190, P. R. China.
Department of Physics and Astronomy and Department of Electrical Engineering and Computer Science, Vanderbilt University, Nashville, TN, 37235, USA.
Adv Mater. 2020 May;32(19):e1908314. doi: 10.1002/adma.201908314. Epub 2020 Apr 2.
Materials possessing structural phase transformations exhibit a rich set of physical and chemical properties that can be used for a variety of applications. In 2D materials, structural transformations have so far been induced by strain, lasers, electron injection, electron/ion beams, thermal loss of stoichiometry, and chemical treatments or by a combination of such approaches and annealing. However, stoichiometry-preserving, purely thermal, reversible phase transitions, which are fundamental in physics and can be easily induced, have not been observed. Here, the fabrication of monolayer Cu Se, a new 2D material is reported, demonstrating the existence of a purely thermal structural phase transition. Scanning tunneling microscopy, scanning transmission electron microscopy, and density functional theory (DFT) identify two structural phases at 78 and 300 K. DFT calculations trace the phase-transition mechanism via the existence/absence of imaginary (unstable) phonon modes at low and high temperatures. In situ, variable-temperature low-energy electron diffraction patterns demonstrate that the phase transition occurs across the whole sample at ≈147 K. Angle-resolved photoemission spectra and DFT calculations show that a degeneracy at the Γ point of the energy bands of the high-temperature phase is lifted in the low-temperature phase. This work opens up possibilities for studying such phase transitions in 2D materials.
具有结构相变的材料展现出一系列丰富的物理和化学性质,可用于多种应用。在二维材料中,迄今为止,结构转变是由应变、激光、电子注入、电子/离子束、化学计量的热损失、化学处理或这些方法与退火的组合诱导产生的。然而,尚未观察到在物理学中具有基础性且能轻易诱导的保持化学计量的纯热可逆相变。在此,报道了一种新型二维材料单层CuSe的制备,证明了纯热结构相变的存在。扫描隧道显微镜、扫描透射电子显微镜和密度泛函理论(DFT)确定了在78 K和300 K时的两个结构相。DFT计算通过低温和高温下虚(不稳定)声子模式的存在与否追踪相变机制。原位变温低能电子衍射图谱表明,相变在≈147 K时在整个样品中发生。角分辨光电子能谱和DFT计算表明,高温相能带的Γ点处的简并在低温相中消除。这项工作为研究二维材料中的此类相变开辟了可能性。
