TY - JOUR
T1 - Correlated Displacement of Dynamic Elastic Dipoles Produces Nonclassical Electrostriction in Zr-Doped Ceria
AU - Pechersky-Savich, Tali
AU - Xu, Boyuan
AU - Varenik, Maxim
AU - Li, Junying
AU - Wachtel, Ellen
AU - Ehre, David
AU - Routh, Prahlad K.
AU - Marcella, Nicholas
AU - Frenkel, Anatoly I.
AU - Qi, Yue
AU - Lubomirsky, Igor
N1 - Publisher Copyright:
© 2024 American Chemical Society.
PY - 2024
Y1 - 2024
N2 - By combining experimental data with density functional theory-based ab initio molecular dynamics modeling, this work provides evidence that nonclassical electrostriction in isovalent Zr-doped ceria is due to the correlated anharmonic motion of dynamic elastic dipoles associated with multiple [ZrO8]-local bonding units with a high Zr concentration (Zr0.1Ce0.9O2). Introduction of 0.5 mol % trivalent or divalent codopants (Sc, Yb, La, or Ca) reduces the longitudinal electrostriction strain coefficient by more than a factor of 10, produces a 3-fold decrease in the relative dielectric permittivity, and increases the elastic modulus. Since these changes depend neither on the radius nor on the valency of the codopant, we conclude that the responsible species are charge-compensating oxygen vacancies (VO). For trivalent dopants (Do0.005Zr0.1Ce0.895O1.9975), oxygen vacancies are present at a concentration ratio 1:40 with respect to Zr, giving, for random distribution, a characteristic interaction distance of ≤2.3 unit cells (1.2 nm). Oxygen vacancies participate in [ZrO7-VO] local bonding units, disrupting the correlated dynamic displacements of the connected [ZrO8]-local bonding units. Such correlated motion of dynamic elastic dipoles may also explain the exponential increase in the longitudinal electrostriction strain coefficient with an increase in Zr concentration to <0.2 mole fraction and must be taken into account for further development of nonclassical electrostrictors based on Zr-doped ceria.
AB - By combining experimental data with density functional theory-based ab initio molecular dynamics modeling, this work provides evidence that nonclassical electrostriction in isovalent Zr-doped ceria is due to the correlated anharmonic motion of dynamic elastic dipoles associated with multiple [ZrO8]-local bonding units with a high Zr concentration (Zr0.1Ce0.9O2). Introduction of 0.5 mol % trivalent or divalent codopants (Sc, Yb, La, or Ca) reduces the longitudinal electrostriction strain coefficient by more than a factor of 10, produces a 3-fold decrease in the relative dielectric permittivity, and increases the elastic modulus. Since these changes depend neither on the radius nor on the valency of the codopant, we conclude that the responsible species are charge-compensating oxygen vacancies (VO). For trivalent dopants (Do0.005Zr0.1Ce0.895O1.9975), oxygen vacancies are present at a concentration ratio 1:40 with respect to Zr, giving, for random distribution, a characteristic interaction distance of ≤2.3 unit cells (1.2 nm). Oxygen vacancies participate in [ZrO7-VO] local bonding units, disrupting the correlated dynamic displacements of the connected [ZrO8]-local bonding units. Such correlated motion of dynamic elastic dipoles may also explain the exponential increase in the longitudinal electrostriction strain coefficient with an increase in Zr concentration to <0.2 mole fraction and must be taken into account for further development of nonclassical electrostrictors based on Zr-doped ceria.
UR - http://www.scopus.com/inward/record.url?scp=85200821825&partnerID=8YFLogxK
U2 - 10.1021/acs.chemmater.4c00688
DO - 10.1021/acs.chemmater.4c00688
M3 - ???researchoutput.researchoutputtypes.contributiontojournal.article???
AN - SCOPUS:85200821825
SN - 0897-4756
JO - Chemistry of Materials
JF - Chemistry of Materials
ER -