Frank M. Steranka

Bulk GaN based violet light-emitting diodes with high efficiency at very high current density

We present experimental results on III–nitride light-emitting diodes emitting at 410u2009nm, grown on low-defectivity bulk GaN substrates. The epitaxial layers are optimized for high peak efficiency and maintain efficiency at very high current densities. We use a volumetric device architecture with surface roughness to maximize light extraction efficiency. We report an external quantum efficiency of 68% at 180u2009Au2009cm−2. No current crowding is observed at high current density. We also demonstrate flat-line reliable operation to over 1000u2009h.

Bulk GaN flip-chip violet light-emitting diodes with optimized efficiency for high-power operation

We report on violet-emitting III-nitride light-emitting diodes (LEDs) grown on bulk GaN substrates employing a flip-chip architecture. Device performance is optimized for operation at high current density and high temperature, by specific design consideration for the epitaxial layers, extraction efficiency, and electrical injection. The power conversion efficiency reaches a peak value of 84% at 85u2009°C and remains high at high current density, owing to low current-induced droop and low series resistance.

High light extraction efficiency in bulk-GaN based volumetric violet light-emitting diodes

We report on the light extraction efficiency of III-Nitride violet light-emitting diodes with a volumetric flip-chip architecture. We introduce an accurate optical model to account for light extraction. We fabricate a series of devices with varying optical configurations and fit their measured performance with our model. We show the importance of second-order optical effects like photon recycling and residual surface roughness to account for data. We conclude that our devices reach an extraction efficiency of 89%.