Abstract
Phase boundary provides a fertile ground for exploring emergent phenomena and understanding order parameters couplings in condensed-matter physics. In Pb(Zr1-xTix)O3, there are two types of composition-dependent phase boundary with both technological and scientific importance, i.e. morphotropic phase boundary (MPB) separating polar regimes into different symmetry and ferroelectric/antiferroelectric (FE/AFE) phase boundary dividing polar and antipolar dipole configurations. In contrast with extensive studies on MPB, FE/AFE phase boundary is far less explored. Here, we apply atomic-scale imaging and Rietveld refinement to directly demonstrate the intermediate phase at FE/AFE phase boundary exhibits a rare multipolar Pb-cations ordering, i.e. coexistence of antipolar or polar displacement, which manifests itself in both periodically gradient lattice spacing and anomalous initial hysteresis loop. In-situ electron/neutron diffraction reveals that the same parent intermediate phase can transform into either FE or AFE state depending on suppression of antipolar or polar displacement, coupling with the evolution of long-/short-range oxygen octahedra tilts. First-principle calculations further show that the transition between AFE and FE phase can occur in a low-energy pathway via the intermediate phase. These findings enrich the structural understanding of FE/AFE phase boundary in perovskite oxides.
Highlights
Phase boundary provides a fertile ground for exploring emergent phenomena and understanding order parameters couplings in condensed-matter physics
Despite the fundamentally different nature, it is generally believed that excellent properties at morphotropic phase boundary (MPB) or FE/AFE phase boundary in Pb(Zr1-xTix)O3 arise from the extremely close energies of competing component phases, which makes order parameters be very sensitive to external stimulus12–16
The IP is the most elusive because its structure was first assigned as rhombohedral symmetry without oxygen octahedra tilt while now is considered to be an incommensurately modulated structure in terms of antiphase boundary (APB) or antiphase domain (APD)22–24
Summary
Phase boundary provides a fertile ground for exploring emergent phenomena and understanding order parameters couplings in condensed-matter physics. The second is ferroelectric/antiferroelectric (FE/AFE) phase boundary, where the dipoles ordering state changes abruptly from parallel to antiparallel arrangement.
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