Oxidation of the GaAs semiconductor at the Al₂O₃/GaAs junction

Abstract: Atomic-scale understanding and processing of the oxidation of III-V compound-semiconductor surfaces are essential for developing materials for various devices (e.g., transistors, solar cells, and light emitting diodes). The oxidation-induced defect-rich phases at the interfaces of oxide/III-V junctions significantly affect the electrical performance of devices. In this study, a method to control the GaAs oxidation and interfacial defect density at the prototypical Al2O3/GaAs junction grown via atomic layer dep… Show more

“…26 Thus, GaSb(100)(1 Â 3)-In-O is a hitherto unreported member for the crystalline oxidized III-V surfaces, 27 which have been shown to potentially decrease the defect densities at insulator/III-V interfaces. [28][29][30] The density of disorderinduced point defects can also be expected to decrease on GaSb(100)(1 Â 3)-In-O, but it is still unclear what kind of band structure is formed in the building block(s) of GaSb(100)(1 Â 3)-In-O itself, in relation to the GaSb band gap area. To clarify this, a comparison of the STS curves of GaSb(100)(4 Â 3) and (1 Â 3)-In-O is shown in Fig.…”

Oxidation of GaSb(100) and its control studied by scanning tunneling microscopy and spectroscopy

“…26 Thus, GaSb(100)(1 Â 3)-In-O is a hitherto unreported member for the crystalline oxidized III-V surfaces, 27 which have been shown to potentially decrease the defect densities at insulator/III-V interfaces. [28][29][30] The density of disorderinduced point defects can also be expected to decrease on GaSb(100)(1 Â 3)-In-O, but it is still unclear what kind of band structure is formed in the building block(s) of GaSb(100)(1 Â 3)-In-O itself, in relation to the GaSb band gap area. To clarify this, a comparison of the STS curves of GaSb(100)(4 Â 3) and (1 Â 3)-In-O is shown in Fig.…”

Oxidation of GaSb(100) and its control studied by scanning tunneling microscopy and spectroscopy

“…Figure shows the PL spectra for each of the samples along with the LEED figures of the starting surface of GaAs(100)(6 × 6) and the observed intense (1 × 1)‐InO x as insets. For LEED patterns of the other surfaces, we refer to our previous works . The least amount of nonradiative recombination is observed for the c (4 × 2) sample, and the most for the (1 × 1) sample.…”

“…Indeed, the nature of these interface defects and the methods to control their formation have been the subject of a vast body of investigations (e.g., refs. ). In previous studies, these defect states have been found to arise, among others, from group‐V dimers; group‐V and group‐III dangling bonds; and III‐Ox or V‐Ox phases.…”

“…Thus, the identification of defect origin(s) is an open issue. There appears to be a consensus that the high oxidation state of Ga (i.e., Ga 2 O 3 type) increases defect density and is more harmful than the corresponding oxides of In . However, the mechanism responsible for Ga 2 O 3 ‐related gap states in Ga x In 1− x As remains unclear.…”

“…A potential approach, presented recently, includes the deposition of a thin In layer on GaAs, followed by the oxidation of such In‐terminated GaAs before the growth of an insulator film. This method leads to a crystalline oxidized In‐containing GaAs surface: GaAs(100) c (4 × 2)‐InO x , which is promising to be incorporated into device structures, because it is found to increase photoluminescence (PL) intensity of GaAs, ascribed to result from a reduction in defect state density …”

Decreasing Defect‐State Density of Al₂O₃/Ga_xIn_1−xAs Device Interfaces with InO_x Structures

Preparation and Characterization of Oxide/Semiconductor Interfaces