Graphene/SiO2/p-GaN Diodes: An Advanced Economical Alternative for Electrically Tunable Light Emitters

Advanced materials that combine novel functionality and ease of applicability are central to the development of light‐emitting diodes (LEDs), which is of ever increasing commercial importance. Here a new metal‐insulator‐semiconductor (MIS) LED structure that combines economical fabrication with nove...

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Bibliographic Details
Published in:Advanced functional materials 2013-08, Vol.23 (32), p.4043-4048
Main Authors: Chang, Che-Wei, Tan, Wei-Chun, Lu, Meng-Lin, Pan, Tai-Chun, Yang, Ying-Jay, Chen, Yang-Fang
Format: Article
Language:English
Subjects:
electroluminescence
gallium compounds
graphene
light-emitting diodes
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Summary:Advanced materials that combine novel functionality and ease of applicability are central to the development of light‐emitting diodes (LEDs), which is of ever increasing commercial importance. Here a new metal‐insulator‐semiconductor (MIS) LED structure that combines economical fabrication with novel device properties is reported. The presented MIS‐LED consists of a graphene electrode on p‐GaN substrate separated by an insulating SiO2 layer. It is found that the MIS‐LED possesses a unique tunability of the electroluminescence spectra depending on the bias conditions. Tunnel injection from graphene into the p‐GaN can explain the difference in luminescence spectra under forward and reverse bias. The demonstrated MIS‐LED expands the use of graphene and also possibly allows the direct integration of light emitters with other circuit elements. Metal‐insulator‐semiconductor (MIS) light‐ emitting diodes (LEDs) consisting of a graphene electrode on p‐GaN substrate separated by an insulating SiO2 layer are reported. The novel MIS‐LEDs have a unique tunability of the electroluminescence (EL) spectra depending on the bias conditions. The underlying mechanism can be interpreted as the tunneling of electrons and holes through the insulating layer in both polarities, which is different from the standard p‐n junction model.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.201203035