Development and analysis of thick GaN drift layers on 200 mm CTE-matched substrate for vertical device processing

• Published in: Scientific reports Vol. 13; no. 1; p. 15931
• Main Authors: Gonçalez Filho, Walter, Borga, Matteo, Geens, Karen, Cingu, Deepthi, Chatterjee, Urmimala, Banerjee, Sourish, Vohra, Anurag, Han, Han, Minj, Albert, Hahn, Herwig, Marx, Matthias, Fahle, Dirk, Bakeroot, Benoit, Decoutere, Stefaan
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 23.09.2023; Nature Publishing Group; Nature Portfolio
• Subjects: 639/166/987; 639/925/927/1007; Atomic force microscopy; Conduction; Dislocation; Drift; Electrons; Growth conditions; Humanities and Social Sciences; Microscopy; multidisciplinary; Science; Science (multidisciplinary); Transmission electron microscopy
• ISSN: 2045-2322; 2045-2322
• DOI: 10.1038/s41598-023-42747-1

This work reports the epitaxial growth of 8.5 µm-thick GaN layers on 200 mm engineered substrates with a polycrystalline AlN core (QST by QROMIS) for CMOS compatible processing of vertical GaN power devices. The epitaxial stack contains a 5 μ m thick drift layers with a Si doping density of 2 × 10 16  cm −3 and total threading dislocation density of 4 × 10 8  cm −2 . The thick drift layer requires fine-tuning of the epitaxial growth conditions to keep wafer bow under control and to avoid the formation of surface defects. Diode test structures processed with this epitaxial stack achieved hard breakdown voltages > 750 V, which is shown to be limited by impurity or metal diffusion from the contact metal stack into threading dislocations. Conductive Atomic Force Microscopy (cAFM) reveals some leakage contribution from mixed type dislocations, which have their core structure identified as the double 5/6 atom configuration by scanning transmission electron microscopy images. Modelling of the leakage conduction mechanism with one-dimensional hopping conduction shows good agreement with the experimental data, and the resulting fitting parameters are compared to similar findings on silicon substrates. The outcome of this work is important to understand the possibilities and limitations of vertical GaN devices fabricated on large diameter wafers.