Abstract
Hexagonal boron nitride (hBN) is a wide gap 2D layered material with good insulating properties. Intrinsic point defects in hBN play an important role in its applications as a dielectric in 2D electronic devices. However, the electronic properties of these defects are still poorly understood. We have calculated the structure and properties of a wide range of intrinsic point defects in the bulk of hBN using hybrid density functional theory (DFT). These include vacancies and interstitial states of B and N as well as di- and tri-vacancies. For each isolated defect, multiple charge states are calculated, and for each charge state multiple spin states are investigated. Positions of defect charge transition levels in the band gap of hBN are calculated. In particular, we predict that B vacancies are likely to be negatively charged in contact with graphene and other metals. Calculations of the interaction between vacancies predict that divacancies in both B and N sublattices are strongly binding. Moreover, the interaction of single B and N vacancies in adjacent layers induces the creation of -N–N- and -B–B- molecular bridges, which greatly distort the local structure, leading to local bond weakening. These results provide further insight into the properties of defects which can be responsible for degradation of hBN based devices.
Highlights
Abstract an us Hexagonal boron nitride is a wide gap 2D layered material with good insulating properties
N vacancies in adjacent layers induces the creation of -N–N- and -B–B- molecular bridges, which greatly distort the local structure, leading to local bond weakening. These results provide further insight into the properties of defects which can be responsible for degradation of Hexagonal boron nitride (hBN) based devices
density functional theory (DFT)) calculations to characterize a wide range of point defects in hBN, making predictions for charge transition levels (CTLs), formation energy and spin state
Summary
DFT) calculations to characterize a wide range of point defects in hBN, making predictions for charge transition levels (CTLs), formation energy and spin state. We calculate the ionisation potential (IP) of an hBN slab, which allows us to estimate valence band offsets with different electrodes and discuss defect charge states in the context of electronic devices. The interaction of vacancies in adjacent layers induces the creation of -N–N- and -B–B- molecular bridges, which greatly distort the local structure, leading to local bond weakening These results provide further insight into the properties of defects which can be responsible for degradation of hBN based devices
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