Uncovering the properties of homo-epitaxial GaN devices through cross-sectional infrared nanoscopy

Hossein Zandipour; Felix Kaps; Robin Buschbeck; Maximilian Obst; Aditha Senarath; Richarda Niemann; Niclas S Mueller; Gonzalo Alvarez-Perez; Katja Diaz-Granados; Ryan A Kowalski; Jakob Wetzel; Raghunandan Balasubramanyam Iyer; Matthew Wortel; J. Michael Klopf; Travis Anderson; Alan Jacobs; Mona Ebrish; Lukas M Eng; Alexander Paarman; Susanne C Kehr; Joshua D Caldwell; Thomas G Folland

doi:10.48550/arxiv.2603.08858

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Uncovering the properties of homo-epitaxial GaN devices through cross-sectional infrared nanoscopy

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Uncovering the properties of homo-epitaxial GaN devices through cross-sectional infrared nanoscopy

Hossein Zandipour, Felix Kaps, Robin Buschbeck, Maximilian Obst, Aditha Senarath, Richarda Niemann, Niclas S Mueller, Gonzalo Alvarez-Perez, Katja Diaz-Granados, Ryan A Kowalski, …

ArXiv.org

Cornell University

03/09/2026

DOI: 10.48550/arxiv.2603.08858

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Preprint (Author's original)This preprint has not been evaluated by subject experts through peer review. Preprints may undergo extensive changes and/or become peer-reviewed journal articles. Open Access

Abstract

Validating material performance in electrical devices is crucial to product development. For Gallium Nitride (GaN) devices, evaluating material factors such as defects, dopant concentration, and overall production quality is essential to ensure their performance in advanced electronic and optoelectronic applications. This work demonstrates that scattering-type scanning near-field optical microscopy (s-SNOM) can meet the demanding performance requirements for characterizing homoepitaxial GaN devices. Specifically, we show that combining s-SNOM results in the mid-IR and terahertz (THz) spectral ranges can disentangle carrier and lattice changes in a GaN p-i-n diode, which is not possible using one spectral range alone. We observe strong, resonant near-field signals near the LO phonon mode of GaN that correlate well with point-dipole models. This data shows great sensitivity to the local carrier density, with changes on the order of 1018 cm-3 easily resolved experimentally. Further, we demonstrate high sensitivity to sub-surface defects, which remain a significant challenge for other non-destructive techniques. To validate the power of s-SNOM imaging, our results are compared to traditional metrologies, including micro-Raman mapping and Kelvin Probe Force Microscopy (KPFM). Our results show that s-SNOM shows superior resolution and sensitivity to perturbations, highlighting the power of this technique in semiconductor device characterization.

Physics - Materials Science

Details

Title: Subtitle: Uncovering the properties of homo-epitaxial GaN devices through cross-sectional infrared nanoscopy
Creators: Hossein Zandipour - University of Iowa
Felix Kaps
Robin Buschbeck
Maximilian Obst
Aditha Senarath
Richarda Niemann
Niclas S Mueller
Gonzalo Alvarez-Perez
Katja Diaz-Granados
Ryan A Kowalski
Jakob Wetzel
Raghunandan Balasubramanyam Iyer
Matthew Wortel - University of Iowa
J. Michael Klopf
Travis Anderson
Alan Jacobs
Mona Ebrish
Lukas M Eng
Alexander Paarman
Susanne C Kehr
Joshua D Caldwell
Thomas G Folland
Resource Type: Preprint
Publication Details: ArXiv.org
DOI: 10.48550/arxiv.2603.08858
ISSN: 2331-8422
Publisher: Cornell University; Ithaca, New York
Language: English
Date posted: 03/09/2026
Academic Unit: Physics and Astronomy
Record Identifier: 9985143134602771

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