Abstract
In the current paper, the structure and properties of AlGaN/GaN interfaces are studied, explaining the role of AlGaN layer thickness on the
two-dimensional electron gas (2DEG) formation. It is found that the generation of a continuous electron gas requires AlGaN films with
stable stoichiometry, which can be reached only above a certain critical thickness, ≈6–7 nm in our case (20 at. % Al content). Thinner films
are significantly affected by oxidation, which causes composition variations and structural imperfections leading to an inhomogeneity of the
polarization field and, as a consequence, of the electron density across the interface. Using Kelvin probe force microscopy, this inhomogeneity
can be visualized as variations of the surface potential on the sub-micrometer scale. For heterostructures with layer thickness above the
critical value, the surface potential maps become homogeneous, reflecting a weakening influence of the oxidation on the interface electronic
properties. The 2DEG formation is confirmed by the Hall measurements for these heterostructures
two-dimensional electron gas (2DEG) formation. It is found that the generation of a continuous electron gas requires AlGaN films with
stable stoichiometry, which can be reached only above a certain critical thickness, ≈6–7 nm in our case (20 at. % Al content). Thinner films
are significantly affected by oxidation, which causes composition variations and structural imperfections leading to an inhomogeneity of the
polarization field and, as a consequence, of the electron density across the interface. Using Kelvin probe force microscopy, this inhomogeneity
can be visualized as variations of the surface potential on the sub-micrometer scale. For heterostructures with layer thickness above the
critical value, the surface potential maps become homogeneous, reflecting a weakening influence of the oxidation on the interface electronic
properties. The 2DEG formation is confirmed by the Hall measurements for these heterostructures
| Original language | English |
|---|---|
| Article number | 115703 |
| Journal | Journal of Applied Physics |
| Volume | 127 |
| Issue number | 11 |
| Number of pages | 7 |
| ISSN | 0021-8979 |
| DOIs | |
| Publication status | Published - Mar 2020 |