Three-dimensional GaN micro- and nanorods with a high aspect ratio have recently gained substantial interest in light-emitting diode research, due to their reduced defect density, their nonpolar sidewalls, and their increased active area. Here, we present an alternative geometry for high aspect ratio three-dimensional nanostructures: vertically standing GaN "walls", so-called GaN fins. With high aspect ratios, these GaN fins exhibit the same interesting characteristics as their rod counterparts mentioned above. Beyond that, because of their geometry, the respective material analysis and device processing can be expected to be less complex. We are able to demonstrate the highly reproducible selective area growth of these fins by continuous mode metalorganic vapor phase epitaxy. Fin heights of more than 50 mu m (aspect ratios of nearly 14) could be achieved, and growth rates are as high as 22.8 mu m/h in the beginning of the growth. The sidewalls are smooth nonpolar <11<(2)over bar>0> a-planes, suitable for optoelectronic devices due to the missing quantum-confined Stark effect and less edge effects compared to rods. We investigate the influence of pattern orientation and geometry on the fin morphology. Moreover, the influence of silane flow, which is known to enhance the vertical growth rate, and other growth parameters are systematically explored.

• 出版日期2016-3