DGIST Scholar: n-ZnO:Ga/i-ZnO/p-Si heterojunction light emitting diodes fabricated on patterned Si substrates

Division of Energy Technology 1. Journal Articles

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n-ZnO:Ga/i-ZnO/p-Si heterojunction light emitting diodes fabricated on patterned Si substrates

Title: n-ZnO:Ga/i-ZnO/p-Si heterojunction light emitting diodes fabricated on patterned Si substrates

Author(s): Choi, Mi Kyung ; Han, Won Suk ; Kim, Young Yi ; Kong, Bo Hyun ; Cho, Hyung Koun ; Kim, Jae Hyun ; Seo, Hong-Seok ; Kim, Kang-Pil ; Lee, Jung-Ho

Citation: Journal of Materials Science: Materials in Electronics, v.20, no.12, pp.1214 - 1218

Keywords: EPITAXY ; Ga Film ; Gallium ; Gallium Alloys ; Grain Boundaries ; Grain Boundary Densities ; Grain Size and Shape ; Heterojunctions ; High Density ; High Temperature ; Hole Carriers ; Light emission ; Light emitting Diodes ; Output Power ; Patterned Substrates ; Random Tilting ; Reverse Bias ; Semiconducting Silicon Compounds ; Semiconducting Zinc Compounds ; Si Substrates ; Silicon ; Substrates ; TemPERATURE ; Visible emissions ; Zinc Oxide ; ZnO ; ZnO Layers ; ZnO/P-Si

Abstract: N-ZnO:Gai-ZnO/p-Si heterojunction light-emitting diodes were fabricated on patterned Si substrates with increased interface area where hole carriers were transported to the i-ZnO layer. The patterned Si substrates were prepared by electrochemical etching, and the n-type ZnO:Ga films were deposited by high-temperature sputtering. In the patterned LED, the lower breakdown and greater leakage current under a reverse bias was attributed to the formation of a high density of grain boundaries and random tilting of the c-axis. Compared to an LED without patterning, the patterned substrates resulted in approximately 75% improvement in the output power of visible emission, which was attributed to a 1.33-fold increase in the heterojunction area and the increase in grain boundary density due to grain tilting. © Springer Science+Business Media, LLC 2009.