Issue 15, 2024

Non-classical electrostriction in calcium-doped cerium oxide ceramics

Abstract

Oxygen-defective metal oxides, e.g., acceptor-doped CeO2, demonstrate exceptionally large electrostrictive responses compared to state-of-the-art electromechanically active ceramic materials. Recent investigations focus on trivalent acceptor (A3+) doped ceria and surmise that giant electrostriction on these compounds depends on the electroactive polarizable elastic dipoles associated with electronic defects in the lattice, e.g., oxygen vacancies Image ID:d3ta07512e-t1.gif and polarons. Similarly, to relaxor piezoelectrics, electromechanical responses in doped-ceria strictly depend on the applied field frequency, i.e., time-dependent, revealing a complex interplay between the electro-chemo-mechanic effect in the materials and a loss of properties above 1–10 Hz. This work demonstrates the electromechanical properties of divalent (A2+) calcium-doped ceria (CDC) polycrystalline ceramics with various doping levels (Ce1−xCaxO2−x, x = 0.025–0.15). All the CDC compounds illustrate a steady and high electrostrictive strain coefficient (M33) value exceeding 10−18 m2 V−2 across frequencies between 10−1 and 103 Hz. Notably, the M33 is slightly influenced by the nominal oxygen vacancy concentration, CaO segregation, and the microstructure. These key findings unveil a new form of electromechanical effects in calcium-doped ceria that are rigorously stimulated by the strong electro-steric interaction of Image ID:d3ta07512e-t2.gif pairs.

Graphical abstract: Non-classical electrostriction in calcium-doped cerium oxide ceramics

Supplementary files

Article information

Article type
Paper
Submitted
05 Dec 2023
Accepted
04 Mar 2024
First published
18 Mar 2024

J. Mater. Chem. A, 2024,12, 9173-9183

Non-classical electrostriction in calcium-doped cerium oxide ceramics

A. Kabir, V. B. Tinti, S. Santucci, M. Varenik, S. Griffiths, S. Molin, I. Lubomirsky and V. Esposito, J. Mater. Chem. A, 2024, 12, 9173 DOI: 10.1039/D3TA07512E

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