Size-dependent elasticity of nanocrystalline titania

Bin Chen; Hengzhong Zhang; K. A. Dunphy-Guzman; D. Spagnoli; M. B. Kruger; D. V.S. Muthu; M. Kunz; Sirine Fakra; J. Z. Hu; Q. Z. Guo; Jillian F. Banfield

doi:10.1103/PhysRevB.79.125406

Size-dependent elasticity of nanocrystalline titania

Bin Chen, Hengzhong Zhang, K. A. Dunphy-Guzman, D. Spagnoli, M. B. Kruger, D. V.S. Muthu, M. Kunz, Sirine Fakra, J. Z. Hu, Q. Z. Guo, Jillian F. Banfield

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

59 Citations (Scopus)

Abstract

Synchrotron-based high-pressure x-ray diffraction measurements indicate that compressibility, a fundamental materials property, can have a size-specific minimum value. The bulk modulus of nanocrystalline titania has a maximum at particle size of 15 nm. This can be explained by dislocation behavior because very high dislocation contents can be achieved when shear stress induced within nanoparticles counters the repulsion between dislocations. As particle size decreases, compression increasingly generates dislocation networks (hardened by overlap of strain fields) that shield intervening regions from external pressure. However, when particles become too small to sustain high dislocation concentrations, elastic stiffening declines. The compressibility has a minimum at intermediate sizes.

Original language	English
Article number	125406
Number of pages	8
Journal	Physical Review B
Volume	79
Issue number	12
DOIs	https://doi.org/10.1103/PhysRevB.79.125406
Publication status	Published - 3 Mar 2009
Externally published	Yes

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title = "Size-dependent elasticity of nanocrystalline titania",

abstract = "Synchrotron-based high-pressure x-ray diffraction measurements indicate that compressibility, a fundamental materials property, can have a size-specific minimum value. The bulk modulus of nanocrystalline titania has a maximum at particle size of 15 nm. This can be explained by dislocation behavior because very high dislocation contents can be achieved when shear stress induced within nanoparticles counters the repulsion between dislocations. As particle size decreases, compression increasingly generates dislocation networks (hardened by overlap of strain fields) that shield intervening regions from external pressure. However, when particles become too small to sustain high dislocation concentrations, elastic stiffening declines. The compressibility has a minimum at intermediate sizes.",

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AU - Zhang, Hengzhong

AU - Dunphy-Guzman, K. A.

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AU - Kruger, M. B.

AU - Muthu, D. V.S.

AU - Kunz, M.

AU - Fakra, Sirine

AU - Hu, J. Z.

AU - Guo, Q. Z.

AU - Banfield, Jillian F.

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AB - Synchrotron-based high-pressure x-ray diffraction measurements indicate that compressibility, a fundamental materials property, can have a size-specific minimum value. The bulk modulus of nanocrystalline titania has a maximum at particle size of 15 nm. This can be explained by dislocation behavior because very high dislocation contents can be achieved when shear stress induced within nanoparticles counters the repulsion between dislocations. As particle size decreases, compression increasingly generates dislocation networks (hardened by overlap of strain fields) that shield intervening regions from external pressure. However, when particles become too small to sustain high dislocation concentrations, elastic stiffening declines. The compressibility has a minimum at intermediate sizes.

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Size-dependent elasticity of nanocrystalline titania

Abstract

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