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Modulation and Refinement of In-N re-Bonding of InGaN through in Post-Flow during a Refined Temper Fire Treatment Process
Journal
IEEE Access
Journal Volume
8
Pages
224433-224438
Date Issued
2020
Author(s)
Liu T.-Y
Chen L.-C
Lee C.-C
Cheng Y
Kuan C.-H
Lin R.-M.
CHIEH-HSIUNG KUAN
Abstract
In this article, we describe a subtle method for modulating and refining the indium-nitrogen (In-N) re-bonding effect of InGaN by employing an In post-flow during temper fire ( $\Delta T = 110\,^{\circ }\text{C}$ ) treatment. After optimizing the In flow rate and the temper fire treatment process, the In content in InGaN quantum wells (QWs) increased from 12.7 to 22.3% and the (102) epitaxy quality of InGaN improved, as revealed by the full-width at half-maximum (FWHM) of the X-ray diffractometry signal decreasing from 410 to 374 arcsec. In addition, the quality of a five InGaN/GaN multiple-QW epilayer surface also improved greatly when applying this technique. Merely by modulating the In post-flow rate (0, 5.6, 11.2, 16.8, 22.4, or $28.0~\mu $ mol/min), the InxGa1-xN photoluminescence signal (and FWHM) changed from 449 nm (58 nm) in the absence of In post-flow during the temper fire treatment process, to 523 nm (46 nm) when the In post-flow rate was $11.2~\mu $ mol/min, and to 534 nm (55 nm) when the In post-flow rate was $28.0~\mu $ mol/min. This technique is, therefore, effective at improving the InGaN quality and compensating for the In-N bond desorption rate. ? 2013 IEEE.
Subjects
Fires; Flow rate; Full width at half maximum; III-V semiconductors; Semiconductor quantum wells; X ray diffraction analysis; Desorption rate; InGaN quantum wells; InGaN/GaN; Photoluminescence signals; Treatment process; Semiconductor alloys
Type
journal article