Electromechanical dopant-defect interaction in acceptor-doped ceria

Ahsanul Kabir; Victor Buratto Tinti; Maxim Varenik; Igor Lubomirsky; Vincenzo Esposito

doi:10.1039/d0ma00563k

Electromechanical dopant-defect interaction in acceptor-doped ceria

Ahsanul Kabir, Victor Buratto Tinti, Maxim Varenik, Igor Lubomirsky, Vincenzo Esposito

Research output: Contribution to journal › Article › peer-review

15 Scopus citations

Abstract

Oxygen defective cerium oxide CeO2-δ exhibits a non-classical giant electromechanical response that is superior to that of lead-based electrostrictors. In this work, we report the key-role of acceptor dopants, with different size and valence (Mg2+, Sc3+, Gd3+, and La3+), on polycrystalline bulk ceria. Different dopants tune the electrostrictive properties by changing the electrosteric dopant-defect interactions. We find two distinct electromechanical behaviors: when the interaction is weak (dopant-vacancy binding energy ≤0.3 eV), electrostriction displays a high coefficient (M33), up to 10-17 (m V-1)2, with strongly time-dependent effects. In contrast, we observe no time-dependent effects when the interaction becomes strong (≥0.6 eV).

Original language	English
Pages (from-to)	2717-2720
Number of pages	4
Journal	Materials Advances
Volume	1
Issue number	8
DOIs	https://doi.org/10.1039/d0ma00563k
State	Published - 2020
Externally published	Yes

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© The Royal Society of Chemistry.

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abstract = "Oxygen defective cerium oxide CeO2-δ exhibits a non-classical giant electromechanical response that is superior to that of lead-based electrostrictors. In this work, we report the key-role of acceptor dopants, with different size and valence (Mg2+, Sc3+, Gd3+, and La3+), on polycrystalline bulk ceria. Different dopants tune the electrostrictive properties by changing the electrosteric dopant-defect interactions. We find two distinct electromechanical behaviors: when the interaction is weak (dopant-vacancy binding energy ≤0.3 eV), electrostriction displays a high coefficient (M33), up to 10-17 (m V-1)2, with strongly time-dependent effects. In contrast, we observe no time-dependent effects when the interaction becomes strong (≥0.6 eV).",

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AU - Buratto Tinti, Victor

AU - Varenik, Maxim

AU - Lubomirsky, Igor

AU - Esposito, Vincenzo

PY - 2020

Y1 - 2020

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AB - Oxygen defective cerium oxide CeO2-δ exhibits a non-classical giant electromechanical response that is superior to that of lead-based electrostrictors. In this work, we report the key-role of acceptor dopants, with different size and valence (Mg2+, Sc3+, Gd3+, and La3+), on polycrystalline bulk ceria. Different dopants tune the electrostrictive properties by changing the electrosteric dopant-defect interactions. We find two distinct electromechanical behaviors: when the interaction is weak (dopant-vacancy binding energy ≤0.3 eV), electrostriction displays a high coefficient (M33), up to 10-17 (m V-1)2, with strongly time-dependent effects. In contrast, we observe no time-dependent effects when the interaction becomes strong (≥0.6 eV).

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Electromechanical dopant-defect interaction in acceptor-doped ceria

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