English

Alloying strategy for two-dimensional GaN optical emitters

Materials Science 2017-11-01 v4

Abstract

The recent progress in formation of two-dimensional (2D) GaN by a migration-enhanced encapsulated technique opens up new possibilities for group III-V 2D semiconductors with a band gap within the visible energy spectrum. Using first-principles calculations we explored alloying of 2D-GaN to achieve an optically active material with a tuneable band gap. The effect of isoelectronic III-V substitutional elements on the band gaps, band offsets, and spatial electron localization is studied. In addition to optoelectronic properties, the formability of alloys is evaluated using impurity formation energies. A dilute highly-mismatched solid solution 2D-GaN1x_{1-x}Px_x features an efficient band gap reduction in combination with a moderate energy penalty associated with incorporation of phosphorous in 2D-GaN, which is substantially lower than in the case of the bulk GaN. The group-V alloying elements also introduce significant disorder and localization at the valence band edge that facilitates direct band gap optical transitions thus implying the feasibility of using III-V alloys of 2D-GaN in light-emitting devices.

Keywords

Cite

@article{arxiv.1707.04625,
  title  = {Alloying strategy for two-dimensional GaN optical emitters},
  author = {C. Pashartis and O. Rubel},
  journal= {arXiv preprint arXiv:1707.04625},
  year   = {2017}
}

Comments

14 pages, 4 figures, 1 table

R2 v1 2026-06-22T20:47:34.117Z