| Literature DB >> 30993771 |
Zhaolong Chen1,2,3, Zhiqiang Liu1,4, Tongbo Wei1,4, Shenyuan Yang4,5,6, Zhipeng Dou7, Yunyu Wang1, Haina Ci2,3, Hongliang Chang1, Yue Qi2,3, Jianchang Yan1,4, Junxi Wang1,4, Yanfeng Zhang2, Peng Gao2,7,8, Jinmin Li1,4, Zhongfan Liu2,3,9.
Abstract
The growth of single-crystal III-nitride films with a low stress and dislocation density is crucial for the semiconductor industry. In particular, AlN-derived deep-ultraviolet light-emitting diodes (DUV-LEDs) have important applications in microelectronic technologies and environmental sciences but are still limited by large lattice and thermal mismatches between the epilayer and substrate. Here, the quasi-van der Waals epitaxial (QvdWE) growth of high-quality AlN films on graphene/sapphire substrates is reported and their application in high-performance DUV-LEDs is demonstrated. Guided by density functional theory calculations, it is found that pyrrolic nitrogen in graphene introduced by a plasma treatment greatly facilitates the AlN nucleation and enables fast growth of a mirror-smooth single-crystal film in a very short time of ≈0.5 h (≈50% decrease compared with the conventional process), thus leading to a largely reduced cost. Additionally, graphene effectively releases the biaxial stress (0.11 GPa) and reduces the dislocation density in the epilayer. The as-fabricated DUV-LED shows a low turn-on voltage, good reliability, and high output power. This study may provide a revolutionary technology for the epitaxial growth of AlN films and provide opportunities for scalable applications of graphene films.Entities:
Keywords: aluminum nitride; chemical vapor deposition; deep-ultraviolet light-emitting diodes; graphene; quasi-van der Waals epitaxy
Year: 2019 PMID: 30993771 DOI: 10.1002/adma.201807345
Source DB: PubMed Journal: Adv Mater ISSN: 0935-9648 Impact factor: 30.849