Chang Shu-Jui, Chung Ming-Han, Kao Ming-Yi, Lee Shang-Fan, Yu Yi-Hsing, Kaun Chao-Cheng, Nakamura Tetsuya, Sasabe Norimasa, Chu Shang-Jui, Tseng Yuan-Chieh
Japan Synchrotron Radiation Research Institute (JASRI) , 1-1-1 Kouto , Sayo , Hyogo 679-5198 , Japan.
National Synchrotron Radiation Research Center , Hsinchu 30076 , Taiwan.
ACS Appl Mater Interfaces. 2019 Aug 28;11(34):31562-31572. doi: 10.1021/acsami.9b11767. Epub 2019 Aug 14.
Multiferroic materials are strong candidates for reducing the energy consumption of voltage-controlled spintronic devices because of the coexistence of ferroelectric (FE) and magnetic orders in a single phase. In this article, we present a new multiferroic perovskite, GdNiFeO (GFNO), produced via sputtering on a SrTiO substrate. The proposed GFNO is FE and canted antiferromagnetic (AFM) within a monoclinic framework at room temperature. The FE polarization of the GFNO is up to 37 μC/cm. When capped with a Co layer, the resulting heterostructure exhibits voltage-controlled magnetism (VCM). The heterostructured device exhibits two distinct features. First, its VCM depends on the magnitude as well as the polarity of the applied bias, thereby doubling the number of available magnetic readout states under a fixed voltage. Furthermore, the magnetic order of the device can be controlled very effectively within ±1 V. These two characteristics satisfy the requirements for low-power and high-storage technology. Theoretical analysis and experimental results indicate the importance of Ni dopant in regulating the polarity-dependent multiferroicity of this gadolinium ferrite system.
多铁性材料因其在单相中共存铁电(FE)和磁有序性,是降低压控自旋电子器件能耗的有力候选材料。在本文中,我们展示了一种通过在SrTiO衬底上溅射制备的新型多铁性钙钛矿GdNiFeO(GFNO)。所提出的GFNO在室温下单斜晶系框架内具有铁电性和倾斜反铁磁性(AFM)。GFNO的铁电极化高达37 μC/cm²。当覆盖一层Co层时,所得异质结构表现出压控磁性(VCM)。该异质结构器件具有两个显著特征。首先,其VCM取决于所施加偏压的大小和极性,从而在固定电压下使可用磁读出状态的数量增加一倍。此外,器件的磁有序性可以在±1 V范围内非常有效地得到控制。这两个特性满足了低功耗和高存储技术的要求。理论分析和实验结果表明,Ni掺杂剂在调节这种钆铁氧体系统的极性相关多铁性方面具有重要作用。
