posted on 2020-04-13, 19:22authored byHemaprabha Elangovan, Maya Barzilay, Sahar Seremi, Noy Cohen, Yizhe Jiang, Lane W. Martin, Yachin Ivry
Mechanical
displacement in commonly used piezoelectric materials
is typically restricted to linear or biaxial in nature and to a few
percent of the material dimensions. Here, we show that free-standing
BaTiO3 membranes exhibit nonconventional electromechanical
coupling. Under an external electric field, these superelastic membranes
undergo controllable and reversible “sushi-rolling-like”
180° folding–unfolding cycles. This crease-free folding
is mediated by charged ferroelectric domains, leading to giant >3.8
and 4.6 μm displacements for a 30 nm thick membrane at room
temperature and 60 °C, respectively. Further increasing the electric
field above the coercive value changes the fold curvature, hence augmenting
the effective piezoresponse. Finally, it is found that the membranes
fold with increasing temperature followed by complete immobility of
the membrane above the Curie temperature, allowing us to model the
ferroelectric domain origin of the effect.