Authors
Maxim Varenik, Tali Pechersky-Savich, Sergey Khodorov, Erik Gor, Ellen Wachtel, David Ehre, Anatoly I Frenkel, Yue Qi, Petr Yudin, Igor Lubomirsky
Published in
Physical chemistry chemical physics : PCCP. Jul 14, 2026. Epub Jul 14, 2026.
Abstract
We have analyzed the compatibility of the Uchino-Cross small anharmonicity model for chemical bonds with recent observations of giant electrostriction in 10 mol% Zr-doped ceria (ZCO10), which exhibits a large negative longitudinal electrostriction strain coefficient M33 ∼ -10-16 m2 V-2; a negative saturation strain exceeding 250 ppm; and a zero-stress dielectric permittivity . While the small anharmonicity approximation is applicable to strong classical electrostrictors such as PMN-PT15 and to non-classical electrostrictors such as Gd-doped ceria, electrostriction data for ZCO10 cannot be understood within this framework. For ZCO10, the permittivity change (Δε3) associated with the converse electrostriction effect exceeds the zero-stress value , i.e., . Such behavior is incompatible with weak anharmonicity, suggesting that for ZCO10 the anharmonic contribution to the bond-deformation energy is not negligible relative to the harmonic term. This finding agrees with the previously suggested microscopic model based on EXAFS measurements and density functional theory (DFT)-based simulation, which posits that the Zr ion has freedom to move within a certain "free volume". We have also observed that, despite the very large and negative longitudinal response, M33, the transverse coefficient, M31, is found by both direct and converse measurement techniques to be approximately one to two orders of magnitude smaller. Indeed, small M31 is necessary in order to avoid driving the transverse dielectric permittivity negative. These results identify Zr-doped ceria as a material whose electromechanical response requires extending the existing theoretical framework and which opens a pathway for designing electrostrictors that operate beyond the small anharmonicity limit.
PMID:
42447245
Bibliographic data and abstract were imported from PubMed on 15 Jul 2026.
Read full publication at:
Please sign in
to see all details.
Advertisement
Stats
- Recommendations n/a n/a positive of 0 vote(s)
- Views 3
- Comments 0