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Interdependencies of critical radius, critical energy and surface energy (CRESE) in silicon self-assembled nanodots

The interdependence parameters in the growth of silicon self-assembled nanodots are investigated. Accordingly, the critical radius, critical energy change and surface energy can be interpreted in terms of cubic function, where it produced a critical surface energy ? NS * and the corresponding r * an...

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Main Authors: Sakrani, Samsudi, Mat Isa, Ahmad Radzi, Othaman, Zulkafli, Ismail, Abd. Khamim, Wahab, Yussof, Idrees, Fatima Aldaw
Format: Book Section
Published: Trans Tech Publications 2012
Subjects:
Q Science
Online Access:http://eprints.utm.my/id/eprint/35703/
http://dx.doi.org/10.4028/www.scientific.net/AMR.501.189
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spelling my.utm.357032017-08-06T03:33:55Z http://eprints.utm.my/id/eprint/35703/ Interdependencies of critical radius, critical energy and surface energy (CRESE) in silicon self-assembled nanodots Sakrani, Samsudi Mat Isa, Ahmad Radzi Othaman, Zulkafli Ismail, Abd. Khamim Wahab, Yussof Idrees, Fatima Aldaw Q Science The interdependence parameters in the growth of silicon self-assembled nanodots are investigated. Accordingly, the critical radius, critical energy change and surface energy can be interpreted in terms of cubic function, where it produced a critical surface energy ? NS * and the corresponding r * and ?G *, called a CRESE point at a fixed growth temperature T when solved mathematically. It is defined as a limiting point at which equilibrium of the critical parameters take place at a constant temperature. Experiments were performed on the samples of amorphous silicon nanodots fabricated onto different non-crystalline substrates. A further analysis on the ? NS *-T plots revealed inverse linear relationships which converged at a CID point (? o *,T *) when projected near the solidification temperature of silicon. The results suggested strong influence of atomic bonding at the nucleus-surface interface combined with higher surface roughness. In conclusion, there exists an equilibrium condition among the growth parameters which stabilizes the growth of amorphous silicon nanodots, as well as the existence of CRESE's ideal destination (CID). Trans Tech Publications 2012 Book Section PeerReviewed Sakrani, Samsudi and Mat Isa, Ahmad Radzi and Othaman, Zulkafli and Ismail, Abd. Khamim and Wahab, Yussof and Idrees, Fatima Aldaw (2012) Interdependencies of critical radius, critical energy and surface energy (CRESE) in silicon self-assembled nanodots. In: Advanced Materials Research. Trans Tech Publications, Switzerland, pp. 189-193. ISBN 978-303785402-0 http://dx.doi.org/10.4028/www.scientific.net/AMR.501.189 DOI:10.4028/www.scientific.net/AMR.501.189
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
topic Q Science
spellingShingle Q Science
Sakrani, Samsudi
Mat Isa, Ahmad Radzi
Othaman, Zulkafli
Ismail, Abd. Khamim
Wahab, Yussof
Idrees, Fatima Aldaw
Interdependencies of critical radius, critical energy and surface energy (CRESE) in silicon self-assembled nanodots
description The interdependence parameters in the growth of silicon self-assembled nanodots are investigated. Accordingly, the critical radius, critical energy change and surface energy can be interpreted in terms of cubic function, where it produced a critical surface energy ? NS * and the corresponding r * and ?G *, called a CRESE point at a fixed growth temperature T when solved mathematically. It is defined as a limiting point at which equilibrium of the critical parameters take place at a constant temperature. Experiments were performed on the samples of amorphous silicon nanodots fabricated onto different non-crystalline substrates. A further analysis on the ? NS *-T plots revealed inverse linear relationships which converged at a CID point (? o *,T *) when projected near the solidification temperature of silicon. The results suggested strong influence of atomic bonding at the nucleus-surface interface combined with higher surface roughness. In conclusion, there exists an equilibrium condition among the growth parameters which stabilizes the growth of amorphous silicon nanodots, as well as the existence of CRESE's ideal destination (CID).
format Book Section
author Sakrani, Samsudi
Mat Isa, Ahmad Radzi
Othaman, Zulkafli
Ismail, Abd. Khamim
Wahab, Yussof
Idrees, Fatima Aldaw
author_facet Sakrani, Samsudi
Mat Isa, Ahmad Radzi
Othaman, Zulkafli
Ismail, Abd. Khamim
Wahab, Yussof
Idrees, Fatima Aldaw
author_sort Sakrani, Samsudi
title Interdependencies of critical radius, critical energy and surface energy (CRESE) in silicon self-assembled nanodots
title_short Interdependencies of critical radius, critical energy and surface energy (CRESE) in silicon self-assembled nanodots
title_full Interdependencies of critical radius, critical energy and surface energy (CRESE) in silicon self-assembled nanodots
title_fullStr Interdependencies of critical radius, critical energy and surface energy (CRESE) in silicon self-assembled nanodots
title_full_unstemmed Interdependencies of critical radius, critical energy and surface energy (CRESE) in silicon self-assembled nanodots
title_sort interdependencies of critical radius, critical energy and surface energy (crese) in silicon self-assembled nanodots
publisher Trans Tech Publications
publishDate 2012
url http://eprints.utm.my/id/eprint/35703/
http://dx.doi.org/10.4028/www.scientific.net/AMR.501.189
_version_ 1643649814357868544
score 13.214268

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