Geometrically polarized architected dielectrics with apparent piezoelectricity

Author (s): Mocci, A.; Codony, D.; Barceló-Mercader, J.; Arias, I.
Journal: Journal of the Mechanics and Physics of Solids

Volume: 157
Date: 2021

Abstract:
Through the suitable geometry of a repeating unit, a metamaterial can exhibit a property
not present in the base material. Here, we propose a class of low area-fraction, bendingdominated
metamaterials that exhibit apparent piezoelectricity, even though the base material
is not piezoelectric. The proposed metamaterials exploit a universal electromechanical coupling
operative at sub-micron scales, flexoelectricity, and upscale it to the macro-scale through
geometrically-polarized material architecture. We quantify the apparent piezoresponse thanks to
accurate simulations of continuum flexoelectricity. We characterize how apparent piezoelectricity
depends on lattice geometry, orientation, feature size and area fraction. We find that if the
base material is a good flexoelectric, then our low area-fraction designs exhibit piezoelectric
couplings comparable to the best piezoelectric ceramics in bulk. More generally, our work
provides the rules to endow any dielectric metamaterial with apparent piezoelectricity, hence
enabling non-toxic, environmentally friendly and biocompatible materials for electromechanical
transduction.

  
  
  

Bibtex:

@article{MOCCI2021104643,
title = {Geometrically polarized architected dielectrics with apparent piezoelectricity},
journal = {Journal of the Mechanics and Physics of Solids},
volume = {157},
pages = {104643},
year = {2021},
issn = {0022-5096},
doi = {https://doi.org/10.1016/j.jmps.2021.104643},
url = {https://www.sciencedirect.com/science/article/pii/S0022509621002829},
author = {A. Mocci and J. Barceló-Mercader and D. Codony and I. Arias},
keywords = {Metamaterials, Piezoelectricity, Flexoelectricity, Non-centrosymmetry},
abstract = {Through the suitable geometry of a repeating unit, a metamaterial can exhibit a property not present in the base material. Here, we propose a class of low area-fraction, bending-dominated metamaterials that exhibit apparent piezoelectricity, even though the base material is not piezoelectric. The proposed metamaterials exploit a universal electromechanical coupling operative at sub-micron scales, flexoelectricity, and upscale it to the macro-scale through geometrically-polarized material architecture. We quantify the apparent piezoresponse thanks to accurate simulations of continuum flexoelectricity. We characterize how apparent piezoelectricity depends on lattice geometry, orientation, feature size and area fraction. We find that if the base material is a good flexoelectric, then our low area-fraction designs exhibit piezoelectric couplings comparable to the best piezoelectric ceramics in bulk. More generally, our work provides the rules to endow any dielectric metamaterial with apparent piezoelectricity, hence enabling non-toxic, environmentally friendly and biocompatible materials for electromechanical transduction.}
}