11:15 AM–1:51 PM, Wednesday, March 23, 2005
LACC - 406A
Sponsoring Unit:
DCMP
Chair: Dr. Tae-Sik Yoon, Dept. MSE, UCLA
Abstract ID: BAPS.2005.MAR.P18.5
12:03 PM–12:15 PM
Xiaoshu Jiang
M. S. Miao
Walter R. L. Lambrecht
(Case Western Reserve University)
First-principles calculations of the native point defects $V_{Zn}$, $V_{Ge}$, $Zn_{Ge}$ and $Ge_{Zn}$ show that under Zn-poor conditions, the dominant defects are the $Ge_{Zn}$ and $V_{Zn}$. Since these are respectively a donor and an acceptor, one may expect them to attract each other. The formation of complexes of the type $V_{Zn}-Ge_{Zn}-V_{Zn}$ was studied and found to be favorable.A simple molecular model is proposed for the electronic structure of this complex. Optical excitation of electron paramagnetic resonance (EPR) studies by Gehlhoff et al. [1] were used by these authors to extract energy levels in the gap associated with these defects. The model proposed by these authors assumes that the $Ge_{Zn}$ EPR centrum in irradiated samples becomes activated by a two step process in which an electron from a $V_{Zn}^{2-}$ is optically excited to the conduction band and subsequently trapped at a $Ge_{Zn}^{2+}$ site converting the two defects in EPR active sites $V_{Zn}^-$ and $Ge_{Zn}^+$. We instead propose a direct transition between the two defect states without the intervening conduction band and show that our calculated occupation energy levels agree with such a model. The $V_{Ge}$ on the other hand is found to have a high energy formation and to be unstable towards the formation of a $V_{Zn}$ and a $Zn_{Ge}$ antisite. [1] W. Gehlhoff, R. N. Pereira, D. Azamat, A. Hoffmann, and N. Dietz, Physica B {\bf 308-310}, 1015 (2001).
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2005.MAR.P18.5