Prof. Jian Wang and collaborators detected localized magnetic moments induced by atomic vacancies in transition metal dichalcogenide flakes
The emergence of two-dimensional (2D) materials provides an excellent platform for exploring and modulating exotic physical properties in the 2D limit, and has driven the development of modern condensed matter physics and nanoelectronic devices. Among various exotic physical properties, 2D magnetism is one of the most important topics, which shows potential application in spintronics. In recent years, researchers have discovered a series of intrinsic 2D magnetic materials, such as CrI3, Fe3GeTe2, etc. However, most of the yet discovered 2D magnetic materials are instable in atmosphere, which limits further investigation and the application of 2D magnetism. Therefore, the key issue is how to induce magnetism in air-stable 2D materials.
Recently, Prof. Jian Wang at Peking University, in collaboration with Prof. Wenhui Duan at Tsinghua University, and Prof. Yanfeng Zhang at Peking University detected localized magnetic moments induced by Pt vacancies in transition metal dichalcogenide PtSe2 flakes, and revealed the origin and flake-thickness dependence of the localized magnetic moments. The paper entitled “Magnetic Moments Induced by Atomic Vacancies in Transition Metal Dichalcogenide Flakes” was published online in Advanced Materials (https://onlinelibrary.wiley.com/doi/10.1002/adma.202005465). Prof. Jian Wang at Peking University, Prof. Wenhui Duan at Tsinghua University and Prof. Yanfeng Zhang at Peking University are the corresponding authors of this paper. Jun Ge, Tianchuang Luo at Peking University, Zuzhang Lin at Tsinghua University, and Jianping Shi at Wuhan University contributed equally to this work (joint first authors).
PtSe2 flakes with thicknesses of 8-70 nm were grown by chemical vapor deposition (CVD), and their high crystalline quality was confirmed by transmission electron microscopy and selected area electron diffraction. The researchers further fabricated PtSe2 devices of different thicknesses and studied their electrical transport properties. The longitudinal resistance decreases with the decrease of temperature in high temperature regime, which is typical metallic behavior. Interestingly, on further decreasing the temperature, the longitudinal resistance increases logarithmically and then tends to saturate at ultralow temperatures. At low temperatures, isotropic negative magnetoresistance (NMR) is detected when an in-plane magnetic field is applied. Further analysis shows that the logarithmic increase of the longitudinal resistance with the decrease of temperature and the isotropic NMR originate from Kondo effect. The well-known Kondo effect usually arises in a non-magnetic metal doped with magnetic impurities, resulting from the exchange interaction between the spins of conduction electrons of non-magnetic host and magnetic impurities. However, the characterization results have demonstrated that there are no magnetic elements in PtSe2 flakes.
The origin of the localized magnetic moments in PtSe2 flakes is revealed by theoretical calculations. The Pt vacancy defects are inevitable to arise during the growth of the PtSe2 flakes. The Pt vacancies result in an asymmetric distribution of the occupied spin majority and minority states of the p orbitals of the three neighboring selenium atoms, finally giving rise to the localized magnetic moments. Surprisingly, the observed magnetic moments seem to be thickness-dependent. When reducing the thickness of flakes, the localized magnetic moment becomes larger. Theoretically, the local magnetic moment in the sample is mainly contributed by the Pt vacancies on the sample surface. With decreasing thickness of the PtSe2 flake, the surface-to-bulk ratio increases, leading to an increase of relative proportion of surface vacancies. As a result, the averaged magnetic moment induced per defect increases with the decreasing thickness, which is consistent with the experimental observations. This work provides a new route for the modulation of magnetism at the atomic scale in non-magnetic 2D materials, especially in air-stable 2D materials, and has potential significance in the development of spintronics and quantum information.
This work is supported by the National Key R&D Program of China, the National Natural Science Foundation of China, Beijing Natural Science Foundation, the Strategic Priority Research Program of Chinese Academy of Sciences, the Open Research Fund Program of the State Key Laboratory of Low-Dimensional Quantum Physics, Tsinghua University, and the Beijing Advanced Innovation Center for Future Chip (ICFC).
Figure 1. The atomic structure and transport properties of PtSe2 flakes. (a) Atomic-resolution high-angle annular dark-field scanning transmission electron microscopy (HAADF-STEM) image of a few-layer PtSe2 flake showing its 1T phase feature and A–A stacking configuration. (b) Longitudinal resistance of s3 as a function of temperature in log plot from 200 K to 2 K. (c) Isotropic NMR when the magnetic field is applied in ab plane of PtSe2 flake s3. Inset shows the schematic diagram of magnetotransport measurements. θ labels the angle between magnetic field and current. (d) MR at various temperatures when the magnetic field is perpendicular to the current in s3.
Figure 2. Theoretical interpretation for the local magnetic moment in PtSe2 flakes. (a) An illustration of the local magnetic moments (denoted by red arrows) and a Pt-vacancy defect (the blue circle) placed in the topmost layer. (b) Electronic density of states of the p orbitals of the three neighboring selenium atoms of the Pt-vacancy. (c) The energy of different magnetic configurations (labeled by the angle β between the magnetic-moment direction and the z axis), where the energy zero corresponds to the magnetic configuration with out-of-plane magnetic moment (i.e., β = 0).