Formation of ordered nanocluster arrays by self-assembly on nanopatterned Si(100) surfaces

A precisely ordered and precisely located array of 5 nm diameter nanoclusters has been fabricated by first etching into the substrate an array of holes with diameters comparable with the size of nanoclusters sought and then depositing adatoms on the substrate. The severely restricted diffusion field...

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Bibliographic Details
Published in:Surface science 1998-05, Vol.406 (1), p.221-228
Main Authors: Winningham, Thomas A, Gillis, H.P, Choutov, D.A, Martin, Kevin P, Moore, Jon T, Douglas, Kenneth
Format: Article
Language:English
Subjects:
Adatom
Atomic force microscopy
Clusters
Clusters, nanoparticles, and nanocrystalline materials
Condensed matter: structure, mechanical and thermal properties
Cross-disciplinary physics: materials science
rheology
Etching
Exact sciences and technology
Materials science
Methods of crystal growth
physics of crystal growth
Nanoscale materials: clusters, nanoparticles, nanotubes, and nanocrystals
Nucleation
Physics
Self-assembly
Silicon
Structure of solids and liquids
crystallography
Surface diffusion
Theory and models of crystal growth
physics of crystal growth, crystal morphology and orientation
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Summary:A precisely ordered and precisely located array of 5 nm diameter nanoclusters has been fabricated by first etching into the substrate an array of holes with diameters comparable with the size of nanoclusters sought and then depositing adatoms on the substrate. The severely restricted diffusion field defined by the holes dominates nucleation and growth to produce a single nanocluster in each etched hole. Using low energy electron enhanced etching in a DC hydrogen plasma, we transferred an hexagonal array of 18 nm diameter holes with a 22 nm lattice constant from a biologically derived mask into Si(100). After etching, the mask was removed, and the patterned surface was intentionally oxidized in an oxygen plasma. Deposition of 1.2 nm of Ti on the oxidized surface produced an ordered array of 5 nm diameter metal nanoclusters positioned at the etched hole sites. Our methods achieved massively parallel processing at the key fabrication steps of pattern generation, pattern transfer, and nanocluster formation. Therefore, our methods enable rapid fabrication of arrays for fundamental studies and provide a route to manufacturability of nanostructure arrays for technological purposes.
ISSN:0039-6028
1879-2758
DOI:10.1016/S0039-6028(98)00115-0