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Title Direct evidence of Be as an amphoteric dopant in GaN
Author(s) Wahl, U. (IST, Lisbon) ; Correia, J. G. (IST, Lisbon) ; Costa, A. R. G. (KU Leuven) ; Lima, T. A. L. (KU Leuven) ; Moens, J. (KU Leuven) ; Kappers, M. J. (Cambridge U.) ; da Silva, M. R. (Aveiro U., CICECO) ; Pereira, L. M. C. (KU Leuven) ; Vantomme, A. (KU Leuven)
Publication 2022
Collaboration IS634 Collaboration
Published in: Phys. Rev. B 105 (2022) 184112
DOI 10.1103/PhysRevB.105.184112
Accelerator/Facility, Experiment CERN ISOLDE
IS634
Keywords p-GaN ; acceptor doping ; Be ; emission channeling ; lattice location
Abstract The interest in Be as an impurity in GaN stems from the challenge to understand why GaN can be doped p type with Mg, while this does not work for Be. While theory has actually predicted an acceptor level for Be that is shallower than Mg, it was also argued that Be is not a suitable acceptor because its am-photeric nature, i.e. its tendency to occupy substitutional Ga as well as interstitial sites, would be considerably more pronounced than for Mg and hence lead to self-compensation. Using the emission channeling technique at the ISOLDE/CERN facility, we determined the lattice location of 11Be (t1/2 = 13.8 s) in different doping types of GaN as a function of implantation temperature. We find within an accuracy of 0.08 Å that the location of interstitial Be is the one predicted by theory. The room temperature interstitial fraction of 11Be was correlated with the GaN doping type, being highest (up to  80%) in p type and lowest in n-GaN, thus giving direct evidence for the amphoteric character of Be. We find that interstitial 11Be fractions are generally much higher than for Mg, which confirms that indeed self-compensation should be consid-erably more pronounced for Be. With rising implantation temperature, an increasing conversion of interstitial to substitutional Be is observed, involving at least two clearly identifiable steps at 50–150 °C and 350–500 °C. This suggests that the migration of interstitial Be may be subject to two different activation ener-gies.
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publication: © 2022-2024 American Physical Society
Submitted by [email protected]

 


 Record created 2022-05-27, last modified 2023-08-10


Postprint from Phys. Rev. B 105 (2022) 184112:
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