skip to main content
OSTI.GOV title logo U.S. Department of Energy
Office of Scientific and Technical Information

Title: Oxidation of aluminum nanoclusters

Journal Article · · Physical Review. B, Condensed Matter and Materials Physics
 [1]; ; ; ;  [1];  [2]
  1. Collaboratory for Advanced Computing and Simulations, Department of Materials Science and Engineering, Department of Physics and Astronomy, Department of Computer Science, University of Southern California, Los Angeles, California 90089-0242 (United States)
  2. Graduate School of Engineering, Nagoya Institute of Technology, Nagoya 466-8555 (Japan)
+ Show Author Affiliations

The dynamics of oxidation of aluminum nanoclusters (20 nm diameter) is investigated using a parallel molecular dynamics approach based on variable charge interatomic interactions due to Streitz and Mintmire that include both ionic and covalent effects. Simulations are performed for both canonical ensembles for molecular oxygen (O{sub 2}) environments and microcanonical ensembles for molecular (O{sub 2}) and atomic (O{sub 1}) oxygen environments. Structural and dynamic correlations in the oxide region are calculated, as well as the evolution of charges, surface oxide thickness, diffusivities of atoms, and local stresses. In the microcanonical ensemble, the oxidizing reaction becomes explosive in both molecular and atomic oxygen environments due to the enormous energy release associated with Al-O bonding. Local stresses in the oxide scale cause rapid diffusion of aluminum and oxygen atoms. Analyses of the oxide scale reveal significant charge transfer and a variation of local structures from the metal-oxide interface to the oxide-environment interface. In the canonical ensemble, oxide depth grows linearly in time until {approx}30 ps, followed by saturation of oxide depth as a function of time. An amorphous oxide layer of thickness {approx}40 A is formed after 466 ps, in good agreement with experiments. The average mass density in the oxide scale is 75% of the bulk alumina density. Evolution of structural correlation in the oxide is analyzed through radial distribution and bond angles. Through detailed analyses of the trajectories of O atoms and their formation of OAl{sub n} structures, we propose a three-step process of oxidative percolation that explains deceleration of oxide growth in the canonical ensemble.

OSTI ID:
20719025
Journal Information:
Physical Review. B, Condensed Matter and Materials Physics, Vol. 71, Issue 20; Other Information: DOI: 10.1103/PhysRevB.71.205413; (c) 2005 The American Physical Society; Country of input: International Atomic Energy Agency (IAEA); ISSN 1098-0121
Country of Publication:
United States
Language:
English

Similar Records

Multiscale atomistic simulation of metal-oxygen surface interactions: methodological development, theoretical investigation, and correlation with experiment. Final report
Technical Report · Sun Sep 30 00:00:00 EDT 2007 · OSTI ID:20719025
On the relationship between non-stoichiometry and passivity breakdown in ultra-thin oxides: combined depth-dependent spectroscopy, Mott-Schottky analysis and molecular dynamics simulation studies
Journal Article · Fri Feb 06 00:00:00 EST 2009 · Journal of Physical Chemistry C, 113(9):3502-3511 · OSTI ID:20719025
+2 more
Liquid Water from First Principles: Validation of Different Sampling Approaches
Journal Article · Thu May 20 00:00:00 EDT 2004 · Journal of Physical Chemistry B: Materials, Surfaces, Interfaces, amp Biophysical · OSTI ID:20719025
+9 more

Related Subjects

75 CONDENSED MATTER PHYSICS
SUPERCONDUCTIVITY AND SUPERFLUIDITY
ALUMINIUM
ALUMINIUM OXIDES
AMORPHOUS STATE
BOND ANGLE
CHARGE EXCHANGE
COMPUTERIZED SIMULATION
CORRELATIONS
COVALENCE
CRYSTAL GROWTH
DENSITY
DIFFUSION
INTERFACES
LAYERS
MOLECULAR DYNAMICS METHOD
NANOSTRUCTURES
OXIDATION
OXYGEN
SPATIAL DISTRIBUTION
STRESSES
SURFACES
THICKNESS
TIME DEPENDENCE