A negative surface energy for alumina

11 April 2004

journal article
research article
Published by Springer Nature in Nature Materials

Vol. 3 (5) , 289-293
https://doi.org/10.1038/nmat1106

Abstract

The surface energy of a solid measures the energy cost of increasing the surface area. All normal solids therefore have a positive surface energy-if it had been negative, the solid would disintegrate. For this reason it is also generally believed that when certain ceramics can be found in a highly porous form, this is a metastable state, which will eventually sinter into the bulk solid at high temperatures. We present theoretical evidence suggesting that for theta-alumina, the surface energy is strongly dependent on the size of the crystallites, and that for some facets it is negative for thicknesses larger than approximately 1 nm. This suggests a completely new picture of porous alumina in which the high-surface-area, nanocrystalline form is the thermodynamic ground state. The negative surface energy is found to be related to a particularly strongly adsorbed state of dissociated water on some alumina surfaces. We also present new experimental evidence based on infrared spectroscopy, in conjunction with X-ray diffraction and surface-area measurements, that theta-alumina has indeed very stable surface OH groups at high temperatures, and that this form of alumina does not sinter even at temperatures up to 1,300 K.

Keywords

This publication has 26 references indexed in Scilit:

The stability of the hydroxylated (0001) surface of α-Al2O3
The Journal of Chemical Physics, 2003
Surface properties of metastable alumina: A comparative study of κ- and $α - {Al}_{2} O_{3}$
Physical Review B, 2003
Hydroxyl Groups on γ-Alumina Surfaces: A DFT Study
Journal of Catalysis, 2002
Energetics of nanocrystalline TiO ₂
Proceedings of the National Academy of Sciences, 2002
Phase stability and structure of spinel-based transition aluminas
Physical Review B, 2000
Sapphire (0001) Surface, Clean and with $d$ -Metal Overlayers
Physical Review Letters, 1999
The Chemistry of Water on Alumina Surfaces: Reaction Dynamics from First Principles
Science, 1998
Electronic and optical properties of $θ - {Al}_{2} O_{3}$ and comparison to $α - {Al}_{2} O_{3}$
Physical Review B, 1998
Surface Energies and Thermodynamic Phase Stability in Nanocrystalline Aluminas
Science, 1997
Structures and transformation mechanisms of the η, γ and θ transition aluminas
Acta crystallographica Section B, Structural science, crystal engineering and materials, 1991