Wafer-scale Transfer Route for Top-down III-nitride Nanowire LED Arrays Based on the Femtosecond Laser Lift-off Technique

Overview

Journal Microsyst Nanoeng

Date 2021 Sep 27

PMID 34567746

Citations 6

Authors

Nursidik Yulianto

Andam Deatama Refino

Alina Syring

Nurhalis Majid

Shinta Mariana

Patrick Schnell

Ruri Agung Wahyuono

Kuwat Triyana

Florian Meierhofer

Winfried Daum

Fatwa F Abdi

Tobias Voss

Hutomo Suryo Wasisto

Andreas Waag

Affiliations

Soon will be listed here.

Abstract

The integration of gallium nitride (GaN) nanowire light-emitting diodes (nanoLEDs) on flexible substrates offers opportunities for applications beyond rigid solid-state lighting (e.g., for wearable optoelectronics and bendable inorganic displays). Here, we report on a fast physical transfer route based on femtosecond laser lift-off (-LLO) to realize wafer-scale top-down GaN nanoLED arrays on unconventional platforms. Combined with photolithography and hybrid etching processes, we successfully transferred GaN blue nanoLEDs from a full two-inch sapphire substrate onto a flexible copper (Cu) foil with a high nanowire density (~10 wires/cm), transfer yield (~99.5%), and reproducibility. Various nanoanalytical measurements were conducted to evaluate the performance and limitations of the -LLO technique as well as to gain insights into physical material properties such as strain relaxation and assess the maturity of the transfer process. This work could enable the easy recycling of native growth substrates and inspire the development of large-scale hybrid GaN nanowire optoelectronic devices by solely employing standard epitaxial LED wafers (i.e., customized LED wafers with additional embedded sacrificial materials and a complicated growth process are not required).

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