Acceptor activation of Mg-doped GaN—Effects of N2/O2 vs N2 as ambient gas during annealingShow others and affiliations
2023 (English)In: Journal of Applied Physics, ISSN 0021-8979, E-ISSN 1089-7550, Vol. 134, no 3, article id 035701Article in journal (Refereed) Published
Abstract [en]
Here, we investigate the effects of O2:N2 (1:1) as ambient gas as compared with pure N2 during activation annealing of Mg as p-type doping in GaN layers grown by MOCVD. The purpose is to understand the impact of O2 on the resulting free hole concentration and hole mobility using SIMS, XRD, STEM, AFM, and Hall effect measurements. Even though the presence of O2 in the ambient gas during annealing is very effective in reducing the H level of the Mg-doped GaN layers, the maximum achievable hole concentration and mobility is still higher with pure N2. The differences are explained by an in-diffusion of O to the GaN layer acting as n-dopant and, thus, giving rise to a compensation effect. The Mg-H complexes at substitutional (MgGa), i.e., the electrically active acceptor sites that provide free holes, are preferentially activated by annealing with N2 only as ambient gas, while annealing with O2:N2 (1:1) also dissociates electrically inactive Mg-H complexes resulting in much less residual H. At the lower growth pressure of 150 mbar compared to higher growth pressure of 300 mbar, an increasing carbon incorporation leads to a compensation effect drastically reducing the free hole concentration while the mobility is unaffected. © 2023 Author(s).
Place, publisher, year, edition, pages
American Institute of Physics Inc. , 2023. Vol. 134, no 3, article id 035701
Keywords [en]
Chemical activation, Gallium nitride, Hall mobility, Hole concentration, Hole mobility, III-V semiconductors, Magnesium compounds, Acceptor activation, Activation annealing, Ambient gas, Compensation effects, Free hole concentration, GaN layers, Growth pressure, Mg-doping, P-type doping, XRD, Annealing
National Category
Condensed Matter Physics
Identifiers
URN: urn:nbn:se:ri:diva-65990DOI: 10.1063/5.0139114Scopus ID: 2-s2.0-85166039478OAI: oai:DiVA.org:ri-65990DiVA, id: diva2:1790641
Note
Correspondence Address: A. Kumar; RISE Research Institutes of Sweden, Lund, Scheelevägen 17, SE-223 63, Sweden; P. Ramvall; RISE Research Institutes of Sweden, Lund, Scheelevägen 17, SE-223 63, Sweden;
This project has received funding from the ECSEL Joint Undertaking (JU) under Grant Agreement No. 826392. The JU receives support from the European Union's Horizon 2020 research and innovation program and Austria, Belgium, Germany, Italy, Slovakia, Spain, Sweden, Norway, and Switzerland.
2023-08-232023-08-232023-08-23Bibliographically approved