Abstract
Understanding formation and distribution of defects in GaN substrates and device layers is needed to improve device performance in rf and power electronics. Here we utilize conductive atomic force microscopy (c-AFM) for studying defect-related leakage paths in an unintentionally doped GaN film formed by nanowire reformation. A nanoscopic Schottky contact is formed between the c-AFM probe and the GaN surface, which, under reverse-bias conditions, reveals local leakage currents at the positions of the nanowires. Cathodoluminescence shows these areas to be dominated by yellow-band luminescence, in contrast to the surrounding GaN matrix, which mainly shows near-band-gap luminescence. These results are attributed to a high density of native and residual defects, confined to the nanowires. In addition, we use anodic oxidation to map defect-related conductive paths through locally induced growth of gallium oxide. The oxide yield, which is known to depend on the local electric field strength between the AFM tip and the sample, correlates well with the level of reverse-bias leakage current. Local irregularities in oxide height reveal extended oxidation attributed to defect-related deep-level states. Thisis confirmed by controlled dissolution of the oxide in NaOH, showing that a deeper oxide film is grown over areas where defect-related conductive paths are formed. Finally, we demonstrate how this approach can be used as a quick and easy diagnostic tool for evaluating the influence of specific growth conditions and process steps on defect-induced leakage current levels and defect distribution in GaN structures, demonstrating its potential for accelerated test of leakage degradation at critical positions in GaN-based devices. (Less)
Highlights
GaN combines several distinct semiconductor properties, such as wide band gap, high charge density, high electron mobility, and appreciable temperature tolerance, making it a prominent candidate for next-generation rf and high-power electronics
The average CL emission from the coalesced layers shows two features, a peak at 3.4 eV corresponding to near-band-gap emission (NBE) from GaN and a broader band centered at 2.2 eV, referred to as the yellow-band (YB), generally associated with point defects
Anodic oxidation enabled by conductive atomic force microscopy (c-AFM) was used as a surface diagnostic tool for visualization and analysis of defect-assisted local leakage current in a GaN surface, formed by growth and reformation of GaN NW arrays
Summary
GaN combines several distinct semiconductor properties, such as wide band gap, high charge density, high electron mobility, and appreciable temperature tolerance, making it a prominent candidate for next-generation rf and high-power electronics. A Schottky junction formed at the tip-surface interface allows trap-assisted tunneling to be locally revealed by the reverse-bias leakage current and onset of anodic oxidation. AFM-induced oxide films are selfselectively growing only on areas which show local leakage current in the reverse-biased Schottky barrier configuration, which can be correlated with electrically active dislocations and point defects. The investigated GaN surfaces, obtained by reformation of NW arrays, comprise a pattern of different areas, originating from different epitaxial growth steps, where both the NW growth and the reformation utilize conditions that are radically different from conventional growth by MOVPE As such, they enable a very efficient suppression of dislocations [4], but they provide conditions for incorporation of significantly different levels of point defects. A tool for fast characterization and improved understanding of point defects and their local distribution in the reformed GaN surfaces, as demonstrated here, is an essential step towards the development of affordable high-quality GaN substrates
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