Kilovolt-Class β-Ga2O3 Field-Plated Schottky Barrier Diodes with MOCVD-Grown Intentionally 1015 cm-3 Doped Drift Layers

Abstract

We report on the growth optimization of intentionally low-doped (1015 cm-3) high-quality β-Ga2O3 drift layers up to 10 μ m thick via MOCVD and the fabrication of kilovolt-class field plated Schottky barrier diodes on these thick drift layers. Homoepitaxial growth was performed on (010) 1015 cm-3 substrates using TMGa as the Ga precursor. Growth parameters were systematically optimized to determine the best conditions for high quality thick growths with the given reactor geometry. Chamber pressure was found to improve the growth rate, mobility, and roughness of the samples. Growth rates of up to 7.2 μ m/hr., thicknesses of up to 10 μ m, Hall mobilities of up to 176 cm2/Vs, RMS roughness down to 5.45 nm, UID concentrations as low as 2 × 1015 cm-3, and controllable intentional doping down to 3 × 1015 cm-3 were achieved. Field plated Schottky barrier diodes (FP-SBDs) were fabricated on a 6.5 × 1015 cm-3 intentionally doped 10 μ m thick film to determine the electrical performance of the MOCVD-grown material. The FP-SBD was found to have current density >100 A/cm2 at 3 V forward bias with a specific differential on resistance (Ron,sp) of 16.22 m.cm2 and a turn on voltage of 1 V. The diodes were found to have high quality anode metal/semiconductor interfaces with an ideality factor of 1.04, close to unity. Diodes had a maximum breakdown voltage of 1.50 kV, leading to a punch-through maximum field of 2.04 MV/cm under the anode metal, which is a state-of-the-art result for SBDs on MOCVD-grown (010) drift layers.