Giant thermally-enhanced electrostriction and polar surface phase in L a2 M o2 O9 oxygen ion conductors

Qian Li, Teng Lu, Jason Schiemer, Nouamane Laanait, Nina Balke, Zhan Zhang, Yang Ren, Michael A. Carpenter, Haidan Wen, Jiangyu Li, Sergei V. Kalinin, Yun Liu

    Research output: Contribution to journalArticlepeer-review

    16 Citations (Scopus)

    Abstract

    Ferroelectrics possess spontaneous electric polarization at macroscopic scales which nonetheless imposes strict limitations on the material classes. Recent discoveries of untraditional symmetry-breaking phenomena in reduced material dimensions have indicated feasibilities to extend polar properties to broader types of materials, potentially opening up the freedom for designing materials with hybrid functionalities. Here, we report the unusual electromechanical properties of La2Mo2O9 (LAMOX) oxygen ion conductors, systematically investigated at both bulk and surface length levels. We first observed giant electrostriction effects in La2Mo2O9 bulk ceramics that are thermally enhanced in concert with their low-energy oxygen-vacancy hopping dynamics. Moreover, while no clear bulk polarization was detected, the surface phases of LAMOX were found to be manifestly polar, likely originating from the coupling between the intrinsic structural flexibilities with strain gradients (i.e., flexoelectricity) and/or chemical heterogeneities present in the materials. These findings identify La2Mo2O9 as a promising electromechanical material system and suggest that the flexible structural and chemical configurations in ionically active materials could enable fundamentally different venues to accommodate electric polarization.

    Original languageEnglish
    Article number041403
    JournalPhysical Review Materials
    Volume2
    Issue number4
    DOIs
    Publication statusPublished - 27 Apr 2018

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