Molecular-dynamics investigation of the surface stress distribution in a Ge/Si quantum dot superlattice

I. Daruka; A. L. Barabási; S. J. Zhou; T. C. Germann; P. S. Lomdahl; A. R. Bishop

doi:10.1103/PhysRevB.60.R2150

Molecular-dynamics investigation of the surface stress distribution in a Ge/Si quantum dot superlattice

I. Daruka, A. L. Barabási, S. J. Zhou, T. C. Germann, P. S. Lomdahl, A. R. Bishop

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Abstract (may include machine translation)

The surface stress distribution in an ordered quantum dot superlattice is investigated using classical molecular dynamics simulations. We find that the surface stress field induced by various numbers (from 1 to 9) of Ge islands embedded in a Si(001) substrate is in good agreement with analytical expressions based on pointlike embedded force dipoles, explaining the tendency of layered arrays to form vertically aligned columns. The short-ranged nature of this stress field implies that only the uppermost layers affect the surface growth and that their influence decreases rapidly with layer depth.

Original language	English
Pages (from-to)	R2150-R2153
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	60
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevB.60.R2150
State	Published - 1999
Externally published	Yes

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10.1103/PhysRevB.60.R2150

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abstract = "The surface stress distribution in an ordered quantum dot superlattice is investigated using classical molecular dynamics simulations. We find that the surface stress field induced by various numbers (from 1 to 9) of Ge islands embedded in a Si(001) substrate is in good agreement with analytical expressions based on pointlike embedded force dipoles, explaining the tendency of layered arrays to form vertically aligned columns. The short-ranged nature of this stress field implies that only the uppermost layers affect the surface growth and that their influence decreases rapidly with layer depth.",

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AU - Daruka, I.

AU - Barabási, A. L.

AU - Zhou, S. J.

AU - Germann, T. C.

AU - Lomdahl, P. S.

AU - Bishop, A. R.

PY - 1999

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N2 - The surface stress distribution in an ordered quantum dot superlattice is investigated using classical molecular dynamics simulations. We find that the surface stress field induced by various numbers (from 1 to 9) of Ge islands embedded in a Si(001) substrate is in good agreement with analytical expressions based on pointlike embedded force dipoles, explaining the tendency of layered arrays to form vertically aligned columns. The short-ranged nature of this stress field implies that only the uppermost layers affect the surface growth and that their influence decreases rapidly with layer depth.

AB - The surface stress distribution in an ordered quantum dot superlattice is investigated using classical molecular dynamics simulations. We find that the surface stress field induced by various numbers (from 1 to 9) of Ge islands embedded in a Si(001) substrate is in good agreement with analytical expressions based on pointlike embedded force dipoles, explaining the tendency of layered arrays to form vertically aligned columns. The short-ranged nature of this stress field implies that only the uppermost layers affect the surface growth and that their influence decreases rapidly with layer depth.

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JF - Physical Review B - Condensed Matter and Materials Physics

IS - 4

ER -

Molecular-dynamics investigation of the surface stress distribution in a Ge/Si quantum dot superlattice

Abstract (may include machine translation)

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