English

Gap control in phosphorene/BN structures from first principles calculations

Materials Science 2016-10-05 v1

Abstract

Using both DFT as well as G0W0G_0W_0 calculations, we investigate static and dynamic effects on the phosphorene band gap upon deposition and encapsulation on/in BN multilayers. We demonstrate how competing long- and short-range effects cause the phosphorene band gap to increase at low P - BN interlayer spacings, while the band gap is found to drop below that of isolated phosphorene in the BN/P bilayer at intermediate distances around 4 \AA. Subsequent stacking of BN layers, i.e. BN/BN/P and BN/BN/BN/P is found to have a negligible effect at the DFT level while at the G0W0G_0W_0 increased screening lowers the band gap as compared to the BN/P bilayer. Encapsulation between two BN layer is found to increase the phosphorene band gap by a value approximately twice that observed when going from freestanding phosphorene to BN/P. We further investigate the use of the GLLBSC\rm{GLLB-SC} functional as a starting point for G0W0G_0W_0 calculations showing it to, in the case of phosphorene, yield results close to those obtained from GW0@PBEGW_0@\rm{PBE} calculations.

Cite

@article{arxiv.1607.08059,
  title  = {Gap control in phosphorene/BN structures from first principles calculations},
  author = {Lukas Eugen Marsoner Steinkasserer and Simon Suhr and Beate Paulus},
  journal= {arXiv preprint arXiv:1607.08059},
  year   = {2016}
}
R2 v1 2026-06-22T15:05:32.866Z