https://doi.org/10.1140/epjb/e2020-10166-6
Regular Article
Exploration of n- and p-type doping for two-dimensional gallium nitride: charged defect calculation with first principles
1
School of Physics and Electronic Science, Guizhou Normal University,
Guiyang
550025, P.R. China
2
College of Information, Guizhou Finance and Economics University,
Guiyang
550025, P.R. China
a e-mail: luozijiang@mail.gufe.edu.cn
Received:
31
March
2020
Received in final form:
7
May
2020
Published online: 5 August 2020
The calculation of charge transition energy level (CTL) and defect formation energy are of significance to explore potential n-type or p-type doping in materials. Based on the first-principles method, this paper systematically studied the structural, magnetic, and defect properties of 12 kinds of dopants in the two-dimensional hexagonal gallium nitride (2D h-GaN) system. The results show that the most stable charge states (MSCSs) for n-type systems are 0 and 1+, and all the n-type substitutes act as shallow donors. The MSCSs of the p-type systems are 1−, 0 and 1+, and the acceptor ionization energy is distributed higher than the valence band maximum (VBM) from ~1.25 to 2.85 eV, acting as deep acceptors, which will capture electrons (holes) in n-(p-type) 2D h-GaN and affect the carrier conductivity. Thus, it is difficult to achieve p-type doping through a single defect in 2D h-GaN, and complex defects are necessary to achieve p-type doping experimentally.
Key words: Solid State and Materials
© EDP Sciences / Società Italiana di Fisica / Springer-Verlag GmbH Germany, part of Springer Nature, 2020