TY - JOUR
T1 - Oxygen-defective electrostrictors for soft electromechanics
AU - Tinti, Victor Buratto
AU - Han, Jin Kyu
AU - Frederiksen, Valdemar
AU - Chen, Huaiyu
AU - Wallentin, Jesper
AU - Kantor, Innokenty
AU - Lyksborg-Andersen, Anton
AU - Hansen, Thomas Willum
AU - Bae, Garam
AU - Song, Wooseok
AU - Stamate, Eugen
AU - de Florio, Daniel Zanetti
AU - Bruus, Henrik
AU - Esposito, Vincenzo
PY - 2024
Y1 - 2024
N2 - Electromechanical metal oxides, such as
piezoceramics, are often incompatible with soft polymers due to their
crystallinity requirements, leading to high processing temperatures.
This study explores the potential of ceria-based thin films as
electromechanical actuators for flexible electronics. Oxygen-deficient
fluorites, like cerium oxide, are centrosymmetric nonpiezoelectric
crystalline metal oxides that demonstrate giant electrostriction. These
films, deposited at low temperatures, integrate seamlessly with various
soft substrates like polyimide and PET. Ceria thin films exhibit
remarkable electrostriction (M33 > 10−16 m2 V−2) and inverse pseudo-piezo coefficients (e33 > 500 pmV−1),
enabling large displacements in soft electromechanical systems. Our
study explores resonant and off-resonant configurations in the
low-frequency regime (<1 kHz), demonstrating versatility for
three-dimensional and transparent electronics. This work advances the
understanding of oxygen-defective metal oxide electromechanical
properties and paves the way for developing versatile and efficient
electromechanical systems for applications in biomedical devices,
optical devices, and beyond.
AB - Electromechanical metal oxides, such as
piezoceramics, are often incompatible with soft polymers due to their
crystallinity requirements, leading to high processing temperatures.
This study explores the potential of ceria-based thin films as
electromechanical actuators for flexible electronics. Oxygen-deficient
fluorites, like cerium oxide, are centrosymmetric nonpiezoelectric
crystalline metal oxides that demonstrate giant electrostriction. These
films, deposited at low temperatures, integrate seamlessly with various
soft substrates like polyimide and PET. Ceria thin films exhibit
remarkable electrostriction (M33 > 10−16 m2 V−2) and inverse pseudo-piezo coefficients (e33 > 500 pmV−1),
enabling large displacements in soft electromechanical systems. Our
study explores resonant and off-resonant configurations in the
low-frequency regime (<1 kHz), demonstrating versatility for
three-dimensional and transparent electronics. This work advances the
understanding of oxygen-defective metal oxide electromechanical
properties and paves the way for developing versatile and efficient
electromechanical systems for applications in biomedical devices,
optical devices, and beyond.
U2 - 10.1126/sciadv.adq3444
DO - 10.1126/sciadv.adq3444
M3 - Journal article
C2 - 39213346
SN - 2375-2548
VL - 10
JO - Science Advances
JF - Science Advances
IS - 35
M1 - eadq3444
ER -