Silicon diffusion in AlN

In this study, we investigate the diffusion of Si donors in AlN. Amorphous Si1-xNx sputtered on the surface of bulk AlN with low dislocation density is used as a Si source. The diffusion experiments are conducted through isochronal and isothermal annealing in a protective N-2 atmosphere at temperatures between 1500 and 1700 degrees C. The Si depth profiles measured by secondary ion mass spectrometry exhibit a convex boxlike shape with a steep diffusion front. These concentration profiles are best described with a diffusion coefficient that depends on the square of local Si concentration. From the characteristic box-shaped Si profiles, we conclude that diffusion of Si in AlN is mediated by singly negatively charged dopant-vacancy pairs SiAlVAl-. The strong concentration dependence of Si diffusion is due to the electric field associated with the incorporation of Si donors (Si-Al(+1)) on substitutional Al lattice sites and reflects that Si is fully electrically active at diffusion temperature. The experimentally obtained extrinsic Si diffusion coefficient is reduced to intrinsic doping conditions. The temperature dependence of Si diffusion for intrinsic conditions is described by an activation enthalpy of (10.34 +/- 0.32) eV and a pre-exponential factor of 235 (+1485)(-203) cm(2)s(-1). The migration enthalpy of the donor-vacancy pair SiAlVAl- is estimated to be around 3.5 eV. This estimation is based on the activation enthalpy of the transport capacity of SiAlVAl- and theoretical results concerning the formation energy of negatively charged vacancies on Al-sites in AlN. (c) 2023 Author(s). All article content, except where otherwise noted, is licensed under a Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).

Automated summary

In this study, the diffusion of Si donors in AlN is investigated. The experiments show that Si diffusion in AlN is mediated by singly negatively charged dopant-vacancy pairs SiAlVAl-. The strong concentration dependence of Si diffusion can be attributed to the electric field associated with the incorporation of Si donors on substitutional Al lattice sites.