Crystal Symmetry Engineering in Epitaxial Perovskite Superlattices

Xiang Ding, Baishun Yang, Huaqian Leng, Jae Hyuch Jang, Junrui Zhao, Chao Zhang, Sa Zhang, Guixin Cao, Ji Zhang, Rohan Mishra, Jiabao Yi, Dongchen Qi, Zheng Gai, Xiaotao Zu, Sean Li, Bing Huang, Albina Borisevich, Liang Qiao

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Abstract

Interface plays a critical role in determining the physical properties and device performance of heterostructures. Traditionally, lattice mismatch, resulting from the different lattice constants of the heterostructure, can induce epitaxial strain. Over past decades, strain engineering has been demonstrated as a useful strategy to manipulate the functionalities of the interface. However, mismatch of crystal symmetry at the interface is relatively less studied due to the difficulty of atomically structural characterization, particularly for the epitaxy of low symmetry correlated materials on the high symmetry substrates. Overlooking those phenomena restrict the understanding of the intrinsic properties of the as- determined heterostructure, resulting in some long-standing debates including the origin of magnetic and ferroelectric dead layers. Here, perovskite LaCoO3-SrTiO3 superlattice (SL) is used as a model system to show that the crystal symmetry effect can be isolated by the existing interface strain. Combining the state-of-art diffraction and electron microscopy, it is found that the symmetry mismatch of LaCoO3-SrTiO3 SL can be tuned by manipulating the SrTiO3 layer thickness to artificially control the magnetic properties. The work suggests that crystal symmetry mismatch can also be designed and engineered to act as an effective strategy to generate functional properties of perovskite oxides.

Original languageEnglish
Article number2106466
JournalAdvanced Functional Materials
Volume31
Issue number47
DOIs
StatePublished - Nov 18 2021

Funding

L.Q. was supported by the National Natural Science Foundation of China (Grant No. 11774044). H.Y.X. was supported by the NSAF Joint Foundation of China (Grant No. U1530129). The theoretical calculations were performed using the supercomputer resources at TianHe‐1 located at National Supercomputer Center in Tianjin. B.H. and B.Y. were supported by the Science Challenge Project (Grant No. TZ2018004), National Natural Science Foundation of China (NSFC) (Grant Nos. 11634003, 12088101) and NSAF U1930402. Electron microscopy research (J.H.J. and A.Y.B.) was supported by the Materials Sciences and Engineering Division, Office of Science, U.S. Department of Energy, and through a user project supported by ORNL's Center for Nanophase Materials Sciences, sponsored by the Scientific User Facilities Division, Basic Energy Sciences, U.S. Department of Energy. D.Q. acknowledges the support of the Australian Research Council (Grant No. FT160100207). Part of this research was undertaken on the Soft X‐ray Spectroscopy beamline at the Australian Synchrotron, part of ANSTO. J.Y. thanks the fund support from Australian Research Council Future FellowshipFT160100205. R.M. acknowledges the National Science Foundation for support through grant number DMR‐1806147.

Keywords

  • interface
  • octahedral connectivity
  • symmetry engineering

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