JPhys Materials (Jan 2024)

Exploring dielectric properties in atomistic models of amorphous boron nitride

  • Thomas Galvani,
  • Ali K Hamze,
  • Laura Caputo,
  • Onurcan Kaya,
  • Simon M-M Dubois,
  • Luigi Colombo,
  • Viet-Hung Nguyen,
  • Yongwoo Shin,
  • Hyeon-Jin Shin,
  • Jean-Christophe Charlier,
  • Stephan Roche

DOI
https://doi.org/10.1088/2515-7639/ad4c06
Journal volume & issue
Vol. 7, no. 3
p. 035003

Abstract

Read online

We report a theoretical study of dielectric properties of models of amorphous Boron Nitride, using interatomic potentials generated by machine learning. We first perform first-principles simulations on small (about 100 atoms in the periodic cell) sample sizes to explore the emergence of mid-gap states and its correlation with structural features. Next, by using a simplified tight-binding electronic model, we analyse the dielectric functions for complex three dimensional models (containing about 10.000 atoms) embedding varying concentrations of sp ^1 , sp ^2 and sp ^3 bonds between B and N atoms. Within the limits of these methodologies, the resulting value of the zero-frequency dielectric constant is shown to be influenced by the population density of such mid-gap states and their localization characteristics. We observe nontrivial correlations between the structure-induced electronic fluctuations and the resulting dielectric constant values. Our findings are however just a first step in the quest of accessing fully accurate dielectric properties of as-grown amorphous BN of relevance for interconnect technologies and beyond.

Keywords