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Sims Characterization of Thin Thermal Oxide Layers on Polycrystalline Aluminium

Published online by Cambridge University Press:  22 February 2011

F. Degreve
Affiliation:
Cégédur Péchiney, Centre de Recherches, B.P. 27, 38340 Voreppe, France.
J. M. Lang
Affiliation:
Cégédur Péchiney, Centre de Recherches, B.P. 27, 38340 Voreppe, France.
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Abstract

Thermal oxide layers of different thickness (T = 3.5–18 am) covering polycrystalline aluminium sheets were investigated by dynamic SIMS in an ion microscope. Depth profiles of major elements (Al, O), segregated impurities in the oxide layer (Li, Na, Be, Mg) and implanted 18O were recorded for different operating conditions : energy, incident angle, chemical (Ar+ or O2+) and isotopic (16O2+ or 18O2+) nature of the primary beam and oxygen jet to saturate the surface.

The main results are:

- the shape of the depth profiles is very sensitive to operating conditions : the best depth resolution is obtained at low energy (2.5 keV) and the minimal distorsion with an O2 jet, even under O2+ bombardment. Deconvolution would be necessary to deduce the true depth profiles.

- a tremendous enrichment (103 – 104) of the oxide to the Al bulk is observed for Li, Na, Be and Mg via an efficient diffusion mechanism during heat 425°C. Their depth distribution within the oxide layer is heterogenous with surface enrichment for Li and Na and sub-layer (towards the oxide/metal interface) for Be lateral distribution below the interface is also heterogeneous e.g. at the grain boundaries for Be and Na.

- the depth profile of implanted 18O+ versus operating conditions and oxide thickness gives direct information on the dynamic oxidation of Al induced by O2+ sputtering in the first 20 nm.

Type
Research Article
Copyright
Copyright © Materials Research Society 1985

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References

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