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Substrate/oxide interface interaction in LaAlO3/Si structures

Published online by Cambridge University Press:  01 February 2011

T. Busani  and
R.A.B. Devine
T. Busani
Affiliation:
AFRL-VSSE, Kirtland Air Force Base, Albuquerque, NM 87117
R.A.B. Devine
Affiliation:
AFRL-VSSE, Kirtland Air Force Base, Albuquerque, NM 87117
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Abstract

Amorphous lanthanum aluminate films (LaAlO3) were deposited on Si substrates at room temperature using rf sputtering in pure Ar or an Ar/O2 mixture with a stoichiometric target. The film composition was analyzed using XPS and EDX. The evolution of the material resulting from annealing at temperatures in excess of 900 °C was studied using infrared spectroscopy, XPS profiling and AFM. We obtain clear evidence for in-diffusion of Si from the substrate into the dielectric film. FTIR analysis showed only one peak centered at 747 cm−1 with an FWHM of 185 cm−1 for as-deposited samples indicating an amorphous structure. Annealed samples showed very narrow absorptions at 483–510, 607, 695–720 and 811 cm−1. No evidence for SiO2 peaks at ∼1060 cm−1 was observed suggesting that the LaAlO3 structure tends not to reduce into a mixture of SiO2 and a silicide. Short time annealing at 1000 °C results in a broad band at 905 cm−1 which can be interpreted in terms of the formation of a layer rich in Si-O-La bonds. Nitridation of the substrate before oxide deposition and annealing slows the degradation process but does not suppress it. X-ray diffraction analysis of the annealed films indicates a very oriented crystalline structure, yet unidentified, whose direction depends upon the orientation of the Si substrate. The dielectric constant in both annealed and as-deposited films was measured to be less than 14 and the leakage current density was very low. Some mobile charge was detected. This dielectric constant is substantially less than the value ∼ 25 anticipated from bulk, single crystal measurements.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 786: Symposium E – Fundamentals of Novel Oxide/Semiconductor Interfaces , 2003 , E6.12
Copyright
Copyright © Materials Research Society 2004

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