Implementation of graphene multilayer electrodes in quantum dot light-emitting devices

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Implementation of graphene multilayer electrodes in quantum dot light-emitting devices.pdf (1.78 MB)

Date

2015

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Source Title

Applied Physics A: Materials Science and Processing

Print ISSN

0947-8396

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Publisher

Springer Verlag

Volume

120

Issue

3

Pages

1197 - 1203

Language

English

Type

Article

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Abstract

Graphene is a highly attractive candidate for implementation as electrodes in next-generation large-area optoelectronic devices thanks to its high electrical conductivity and high optical transparency. In this study, we show all-solution-processed quantum dot-based light-emitting devices (QD-LEDs) using graphene mono- and multilayers as transparent electrodes. Here, the effect of the number of graphene layers (up to three) on the QD-LEDs performance was studied. While the implementation of a second graphene layer was found to reduce the turn-on voltage from 2.6 to 1.8 V, a third graphene layer was observed to increase the turn-on voltage again, which is attributed to an increased roughness of the graphene layer stack. © 2015, Springer-Verlag Berlin Heidelberg.

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Keywords

Current density , Electrodes , Graphene , Light emission , Monolithic microwave integrated circuits , Multilayers , Optoelectronic devices , Semiconductor quantum dots , Graphene layers , Graphene multilayers , High electrical conductivity , Light emitting devices , Mono- and multilayer , Optical transparency , Transparent electrode , Turn-on voltages , Light emitting diodes

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http://hdl.handle.net/11693/21647

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http://dx.doi.org/10.1007/s00339-015-9304-z

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Department of Electrical and Electronics Engineering