Aug 25, 2015

Reliability studies of vertical GaN devices based on bulk GaN substrates

Highlights

Reliability studies of vertical p-n diodes and junction field effect transistors fabricated on low defect density GaN substrates are discussed.
Vertical device architectures with drift layer thicknesses of 6 to 40 μm and net electron concentrations of 2 × 1015 to 2 × 1016 cm− 3 are realized.
This parameter range is suitable for applications requiring breakdown voltages of 1200V to 5kV.
Measured devices demonstrate power device figure of merit of differential specific on-resistance (Rsp) of 2.8 mΩ-cm2 for a breakdown voltage of 4.1kV.
The improvement in the substrate quality over the last few years has resulted in the fabrication of diodes with pulsed currents of 400A.
Impact ionization based avalanche breakdown has been demonstrated in GaN due to the high quality of the epitaxial layers.
High temperature reverse bias and operating life, temperature humidity bias, temperature cycling, and inductive avalanche tests are reported.
Fundamental failure mechanisms are almost always traced back to the starting substrate material quality and surface morphology post epi growth.
No observation of Rds drift is made for vertical devices fabricated on bulk GaN substrates under the stress conditions mentioned above.

There is great interest in wide band-gap semiconductor devices and most recently in vertical GaN structures for power electronic applications. In this paper initial reliability studies of vertical p–n diodes and vertical junction field effect transistors fabricated on pseudo bulk low defect density (104 to 106 cm− 2) GaN substrates are discussed. Homoepitaxial MOCVD growth of GaN on its native substrate and being able to control the doping in the drift layers in GaN has allowed the realization of vertical device architectures with drift layer thicknesses of 6 to 40 μm and net carrier electron concentrations of 2 × 1015 to 2 × 1016 cm− 3. This parameter range is suitable for applications requiring breakdown voltages of 1200 V to 5 kV with a proper edge termination strategy. Measured devices demonstrate power device figure of merit of differential specific on-resistance (Rsp) of 2.8 mΩ-cm2 for a breakdown voltage of 4.1 kV. The improvement in the substrate quality over the last few years has resulted in the fabrication of diodes with areas as large as 16 mm2, with breakdown voltages exceeding 1200 V, and pulsed (100 μs) currents of 100–400 A. Furthermore, impact ionization based avalanche breakdown has been demonstrated in GaN for the first time due to the high quality of the crystals grown on the native substrates. With these key demonstrations firmly in place, it is necessary to evaluate the reliability performance of vertical GaN devices on bulk GaN substrates. The results of high temperature reverse bias (HTRB), high temperature operating life (HTOL), temperature humidity bias (THB), temperature cycling (TC), and inductive avalanche ruggedness tests conducted on vertical GaN devices packaged in standard power packages are reported. It is observed that fundamental failure mechanisms are almost always traced back to the starting substrate material quality, substrate miscut angle, and surface morphology post epi growth. No observation of Rds drift is made for vertical diodes or transistors fabricated on bulk GaN substrates under the stress conditions mentioned above once a suitable back metal and die attach process is developed.

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