Modeling of X-ray rocking curves for layers after two-stage ion-implantation

Modeling of X-ray rocking curves for layers after two-stage ion-implantation

In this work, we consider the approach for simulation of X-ray rocking curves inherent to InSb(111) crystals implanted with Be+ ions with various energies and doses. The method is based on the semi-kinematical theory of X-ray diffraction in the case of Bragg geometry. A fitting procedure that relies...

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Bibliographic Details
Main Authors: O.I. Liubchenko, V.P. Kladko, O.Yo. Gudymenko
Format: Article
Language:English
Published: National Academy of Sciences of Ukraine. Institute of Semi conductor physics. 2017-10-01
Series:Semiconductor Physics, Quantum Electronics & Optoelectronics
Subjects:
X-ray rocking curve modeling
two-stage implantation
Hooke-Jeeves direct search
strain distribution
Online Access:http://journal-spqeo.org.ua/n3_2017/P355-361abstr.html
Description
Summary:In this work, we consider the approach for simulation of X-ray rocking curves inherent to InSb(111) crystals implanted with Be+ ions with various energies and doses. The method is based on the semi-kinematical theory of X-ray diffraction in the case of Bragg geometry. A fitting procedure that relies on the Hooke–Jeeves direct search algorithm was developed to determine the depth profiles of strain and structural disorders in the ion-modified layers. The thickness and maximum value of strain of ion-modified InSb(111) layers were determined. For implantation energies 66 and 80 keV, doses 25 and 50 µC, the thickness of the strained layer is about 500 nm with the maximum value of strain close to 0.1%. Additionally, an amorphous layer with significant thickness was found in the implantation region.
ISSN:1560-8034
1605-6582

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