Orientation-Dependent eta-Ga2O3 Heterojunction Diode with Atomic Layer Deposition (ALD) Grown NiO
Abstract
This work reports the demonstration of ALD-deposited NiO/eta-Ga2O3 heterojunction diodes (HJDs) on low doped drift layer and highly doped (001) & (100) n+ substrates with experimental observation of a parallel-plane junction electric field as high as 7.5 MV/cm, revealing a crystal orientation dependence in eta-Ga2O3. We use a novel metalorganic precursor bis(1,4-di-tert-butyl-1,3-diazadienyl) (nickel Ni(tBu2DAD)2) with ozone (O3) to deposit NiO. The NiO/eta-Ga2O3 HJD on 7.7 μm-thick HVPE-grown drift region exhibited an on-state current density of ~20 A/cm2 at 5 V, ~10-8 A/cm2 reverse leakage at low reverse bias(-5 V), and a rectifying ratio(Jon/Joff) of ~109. The HJD broke down at ~2.2 kV reverse bias, corresponding to a ~3.4 MV/cm parallel-plane junction electric field, with a noise floor reverse leakage (10-8~10-6 A/cm2, nA) at 80% of the device catastrophic breakdown voltage. The NiO/eta-Ga2O3 HJDs on n+ (001) & (100) highly-doped substrates exhibited breakdown voltages at 12.5-16.0 V and 28.5-70.5 V, respectively, with extracted critical electric field (EC) at 2.30-2.76 MV/cm, and 4.33-7.50 MV/cm, revealing a substrate crystal orientation dependence on breakdown electric field for eta-Ga2O3. The 7.5 MV/cm EC reported here is one of the highest parallel-plane junction electric fields reported in literature.
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