First-Principles Investigation of Low EnergyE′Center Precursors in Amorphous Silica

“…This large variability in the formation energies results from variability in local structure in the ensemble of structures and has been observed in other amorphous dielectrics. 37 To our knowledge this is the first report of defect formation energy in a-Si 3 N 4, so we compare our results to vacancy formation energy in crystalline Si 3 N 4 ploymorphs and point defects in a-SiO 2 . The heat of formation of the nitrogen vacancy in β-Si 3 N 4 was calculated to be 3.6 eV and formation energy for point defects in amorphous SiO 2 were predicted to vary between 1.7 eV and 6.8 eV.…”

“…[27][28][29][30][31][32][33][34][35][36] While structural, electronic, and vibrational properties based on these models have been extensively reported, comprehensive models capturing the effect of inherent local variability in the atomic structure and topological disorder of a-Si 3 N 4 are still lacking. Consequently, theoretical predictions of trap depths based on these models report few distinct levels in the band-gap, as opposed to a range of values as expected from the atomic variability of the amorphous network 37 and reported in recent TSCIS measurements. 26 In this paper, we generate and analyze an ensemble of well-equilibrated, statistically independent, a-Si 3 N 4 structures to characterize the effect of local variability on the structure, mechanical, and electronic properties.…”

“…The heat of formation of the nitrogen vacancy in β-Si 3 N 4 was calculated to be 3.6 eV and formation energy for point defects in amorphous SiO 2 were predicted to vary between 1.7 eV and 6.8 eV. 37 The lower defect formation energy in a-Si 3 N 4 relative to a-SiO 2 explains the comparatively high concentration of defects observed experimentally in a-Si 3 N 4 dielectrics compared to a-SiO 2 , a similar and more commonly used dielectric for electronic applications.…”

“…Similar approaches have been effectively used by other researchers for characterizing structural properties and defect formation energies in amorphous silica. [37][38][39][40] We use a combination of MD simulations with empirical potentials and ab initio structural relaxations to generate the ensemble of well equilibrated, stress-free stoichiometric a-Si 3 N 4 structures. Slow annealing via classical MD simulations followed by density functional theory (DFT) optimization leads to structures with small density of defects and several defect-free ones.…”

Effect of topological disorder on structural, mechanical, and electronic properties of amorphous silicon nitride: An atomistic study

“…This large variability in the formation energies results from variability in local structure in the ensemble of structures and has been observed in other amorphous dielectrics. 37 To our knowledge this is the first report of defect formation energy in a-Si 3 N 4, so we compare our results to vacancy formation energy in crystalline Si 3 N 4 ploymorphs and point defects in a-SiO 2 . The heat of formation of the nitrogen vacancy in β-Si 3 N 4 was calculated to be 3.6 eV and formation energy for point defects in amorphous SiO 2 were predicted to vary between 1.7 eV and 6.8 eV.…”

“…[27][28][29][30][31][32][33][34][35][36] While structural, electronic, and vibrational properties based on these models have been extensively reported, comprehensive models capturing the effect of inherent local variability in the atomic structure and topological disorder of a-Si 3 N 4 are still lacking. Consequently, theoretical predictions of trap depths based on these models report few distinct levels in the band-gap, as opposed to a range of values as expected from the atomic variability of the amorphous network 37 and reported in recent TSCIS measurements. 26 In this paper, we generate and analyze an ensemble of well-equilibrated, statistically independent, a-Si 3 N 4 structures to characterize the effect of local variability on the structure, mechanical, and electronic properties.…”

“…The heat of formation of the nitrogen vacancy in β-Si 3 N 4 was calculated to be 3.6 eV and formation energy for point defects in amorphous SiO 2 were predicted to vary between 1.7 eV and 6.8 eV. 37 The lower defect formation energy in a-Si 3 N 4 relative to a-SiO 2 explains the comparatively high concentration of defects observed experimentally in a-Si 3 N 4 dielectrics compared to a-SiO 2 , a similar and more commonly used dielectric for electronic applications.…”

“…Similar approaches have been effectively used by other researchers for characterizing structural properties and defect formation energies in amorphous silica. [37][38][39][40] We use a combination of MD simulations with empirical potentials and ab initio structural relaxations to generate the ensemble of well equilibrated, stress-free stoichiometric a-Si 3 N 4 structures. Slow annealing via classical MD simulations followed by density functional theory (DFT) optimization leads to structures with small density of defects and several defect-free ones.…”

Effect of topological disorder on structural, mechanical, and electronic properties of amorphous silicon nitride: An atomistic study

“…The simulation cells include a half-sphere of amorphous SiO 2 (the tip) 36 and a poly-(methyl-methacrylate) (PMMA) slab as shown in the snapshot in Figure 1. We use the LAMMPS MD package developed at Sandia National Laboratories 37 and the DREIDING force field to describe the interaction between atoms.…”

Molecular dynamic simulation of tip-polymer interaction in tapping-mode atomic force microscopy

Silica, Silicate, and Aluminosilicate Glasses