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Ion-induced nanopatterns on semiconductor surfaces investigated by grazing incidence x-ray scattering techniques

Carbone, D. LU ; Biermanns, A. ; Ziberi, B. ; Frost, F. ; Plantevin, O. ; Pietsch, U. and Metzger, T. H. (2009) In Journal of Physics Condensed Matter 21(22).
Abstract

In this review we cover and describe the application of grazing incidence x-ray scattering techniques to study and characterize nanopattern formation on semiconductor surfaces by ion beam erosion under various conditions. It is demonstrated that x-rays under grazing incidence are especially well suited to characterize (sub)surface structures on the nanoscale with high spatial and statistical accuracy. The corresponding theory and data evaluation is described in the distorted wave Born approximation. Both ex situ and in situ studies are presented, performed with the use of a specially designed sputtering chamber which allows us to follow the temporal evolution of the nanostructure formation. Corresponding results show a general... (More)

In this review we cover and describe the application of grazing incidence x-ray scattering techniques to study and characterize nanopattern formation on semiconductor surfaces by ion beam erosion under various conditions. It is demonstrated that x-rays under grazing incidence are especially well suited to characterize (sub)surface structures on the nanoscale with high spatial and statistical accuracy. The corresponding theory and data evaluation is described in the distorted wave Born approximation. Both ex situ and in situ studies are presented, performed with the use of a specially designed sputtering chamber which allows us to follow the temporal evolution of the nanostructure formation. Corresponding results show a general stabilization of the ordering wavelength and the extension of the ordering as a function of the ion energy and fluence as predicted by theory. The in situ measurements are especially suited to study the early stages of pattern formation, which in some cases reveal a transition from dot to ripple formation. For the case of medium energy ions crystalline ripples are formed buried under a semi-amorphous thick layer with a ripple structure at the surface being conformal with the crystalline/amorphous interface. Here, the x-ray techniques are especially advantageous since they are non-destructive and bulk-sensitive by their very nature. In addition, the GI x-ray techniques described in this review are a unique tool to study the evolving strain, a topic which remains to be explored both experimentally and theoretically.

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publishing date
type
Contribution to journal
publication status
published
in
Journal of Physics Condensed Matter
volume
21
issue
22
article number
224007
publisher
IOP Publishing
external identifiers
  • scopus:66249091259
ISSN
0953-8984
DOI
10.1088/0953-8984/21/22/224007
language
English
LU publication?
no
id
f3b685a5-a836-4bd7-a895-26fb7060174c
date added to LUP
2021-12-15 11:51:36
date last changed
2022-02-02 02:08:41
@article{f3b685a5-a836-4bd7-a895-26fb7060174c,
  abstract     = {{<p>In this review we cover and describe the application of grazing incidence x-ray scattering techniques to study and characterize nanopattern formation on semiconductor surfaces by ion beam erosion under various conditions. It is demonstrated that x-rays under grazing incidence are especially well suited to characterize (sub)surface structures on the nanoscale with high spatial and statistical accuracy. The corresponding theory and data evaluation is described in the distorted wave Born approximation. Both ex situ and in situ studies are presented, performed with the use of a specially designed sputtering chamber which allows us to follow the temporal evolution of the nanostructure formation. Corresponding results show a general stabilization of the ordering wavelength and the extension of the ordering as a function of the ion energy and fluence as predicted by theory. The in situ measurements are especially suited to study the early stages of pattern formation, which in some cases reveal a transition from dot to ripple formation. For the case of medium energy ions crystalline ripples are formed buried under a semi-amorphous thick layer with a ripple structure at the surface being conformal with the crystalline/amorphous interface. Here, the x-ray techniques are especially advantageous since they are non-destructive and bulk-sensitive by their very nature. In addition, the GI x-ray techniques described in this review are a unique tool to study the evolving strain, a topic which remains to be explored both experimentally and theoretically.</p>}},
  author       = {{Carbone, D. and Biermanns, A. and Ziberi, B. and Frost, F. and Plantevin, O. and Pietsch, U. and Metzger, T. H.}},
  issn         = {{0953-8984}},
  language     = {{eng}},
  number       = {{22}},
  publisher    = {{IOP Publishing}},
  series       = {{Journal of Physics Condensed Matter}},
  title        = {{Ion-induced nanopatterns on semiconductor surfaces investigated by grazing incidence x-ray scattering techniques}},
  url          = {{http://dx.doi.org/10.1088/0953-8984/21/22/224007}},
  doi          = {{10.1088/0953-8984/21/22/224007}},
  volume       = {{21}},
  year         = {{2009}},
}