Bulletin of the American Physical Society
APS March Meeting 2018
Volume 63, Number 1
Monday–Friday, March 5–9, 2018; Los Angeles, California
Session F09: Dielectric and Ferroic Oxides - New Materials
11:15 AM–2:15 PM,
Tuesday, March 6, 2018
LACC
Room: 301A
Sponsoring
Unit:
DMP
Chair: Wei Ren, Shanghai University
Abstract ID: BAPS.2018.MAR.F09.1
Abstract: F09.00001 : Improper Ferroelectricity in Stuffed Aluminate Sodalites for Pyroelectric Energy Harvesting*
11:15 AM–11:51 AM
Presenter:
Hiroki Taniguchi
(Department of Physics, Nagoya University)
Author:
Hiroki Taniguchi
(Department of Physics, Nagoya University)
Lead-based ferroelectric oxides, typically PZT, have so far been considered for pyroelectric energy harvesters due to their large spontaneous polarization and relatively high ferroelectric phase transition temperature, which cooperatively give good pyroelectric coefficient in a useful temperature range. However, giant dielectric permittivity of the lead-based ferroelectric oxides limits the pyroelectric conversion efficiency by suppressing transduction from an induced polarization variation to an output electric field.
Here I show improper ferroelectricity in a stuffed zeolite with an excellent performance for the pyroelectric energy harvesting.1,2) Though spontaneous polarization of the stuffed zeolite is smaller by an order of magnitude than that in the conventional lead-based ferroelectrics, its low permittivity even around the phase transition temperature achieves a comparable level of figure-of-merit as that for PZT. Furthermore, if one focuses on a conversion efficiency per unit weight, the stuffed zeolite largely surpasses PZT due to its fairly light density.
Comprehensive studies employing synchrotron x-ray powder diffractions and first-principles calculations have clarified that the improper ferroelectricity of stuffed zeolite stems from multiple phonon instability in finite k-points of Brillouin zone, which synchronizes with a hopping motion of tetrahedral complex anions filled in voids of an AlO4 zeolite framework.1)
1) Y. Maeda et al., Phys. Rev. Applied 7 (2017) 034012.
2) T. Wakamatsu et al., Phys. status solidi RRL 11 1700009 (2017).
*This work is supported by a Grant-in-Aid for Young Scientists (A) (No.16H06115) and MEXT Element Strategy Initiative Project.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2018.MAR.F09.1
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