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1.2 kV AlGaN/GaN Schottky Barrier Diode Employing As+ Ion Implantation on SiO2 Passivation Layer

Published online by Cambridge University Press:  31 January 2011

Jiyong Lim
Affiliation:
jamdol2@snu.ac.kr, Seoul National University, School of Electrical Engineering, Seoul, Korea, Republic of
Young-Hwan Choi
Affiliation:
wink7@emlab.snu.ac.kr, Seoul National University, School of Electrical Engineering, Seoul, Korea, Republic of
Youngshil Kim Kim
Affiliation:
yskim@emlab.snu.ac.kr, Seoul National University, School of Electrical Engineering, Seoul, Korea, Republic of
Min-Ki Kim
Affiliation:
kmk@emlab.snu.ac.kr, Seoul National University, School of Electrical Engineering, Seoul, Korea, Republic of
Min-Koo Han
Affiliation:
mkh@snu.ac.kr, Seoul National University, School of Electrical Engineering, Seoul, Korea, Republic of
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Abstract

Considerable amount of works have been reported to achieve a high breakdown voltage of AlGaN/GaN heterostructure devices by employing additional process such as SiO2 passivation1,2, floating metal rings and Ni/Au Oxidation3. However, it should be point out that treatment of passivation layer of AlGaN/GaN heterostructure devices has been reported scarcely. As+ ion implantation on SiO2 passivation layer may be a simple and effective to reduce electric field strength to increase breakdown voltages. The cross-sectional view of the proposed AlGaN/GaN Schottky barrier diode is shown in Fig. 1. We fabricated conventional AlGaN/GaN Schottky barrier diode and passivated the device with SiO2 layer of 350 nm thick. Finally As+ ions were implanted on the SiO2 passivation layer. We measured the surface potential of the test samples with electric force microscopy (EFM) in order to verify that implanted As+ ions remained as positively charged ions in SiO2 layer after ion implantation. After ion implantation, 2 dimensional electron gas (2DEG) concentration was increased slightly from 8.28E12 /cm2 to 8.38E12 /cm2 so that the forward current was also increased slightly. Table shows the breakdown voltages of the SBDs before and after As+ ion implantation. After As+ 80 keV 1 × 1E14 atoms/cm2 implantation, the breakdown voltage increased considerably from 604 V to 1204 V due to the edge termination by implanted As+ ions. The reverse leakage current decreased from 80.3 uA/mm to 21.2 nA/mm due to the relaxation of electric field concentration by As+ ion implantation. We verified the electric field relaxation through 2D simulation. After As+ ion implantation, the depletion region curvature under the reverse biased condition became moderate so that the maximum electric field strength was decreased. As+ ion implantation method may be a simple and effective edge termination method for improving the breakdown voltage as well as the leakage current of the proposed AlGaN/GaN SBDs. Proposed AlGaN/GaN SBDs showed high breakdown voltage of 1204 V and low leakage current of 21.2 nA/mm without any considerable decrease of forward characteristics while that of conventional device was 604 V and 80.3 uA/mm, respectively.

Keywords

Type
Research Article
Copyright
Copyright © Materials Research Society 2009

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