We have grown Eu-doped GaN on striped GaN facet structures with {11¯01} faces using a selective-area-growth technique. It was found that the orientation of the Eu-doped GaN facets depends on the Eu doping conditions. Semipolar {nn¯01} (n = 2, 3) facets, which are difficult to form using conventional undoped GaN, can be obtained by changing the growth temperature and the amount of the supplied Eu precursor. InGaN/GaN multiple quantum wells (MQWs) were also fabricated on the Eu-doped semipolar facets, and their structural and luminescence properties were investigated. The MQWs fabricated on the Eu-doped semipolar {22¯01} facets have a photoluminescence decay time of 112–314 ps, which is 10 times shorter than those of conventional (0001) QWs. These results show that the Eu doping of GaN is a promising means of obtaining various semipolar facets, which can contribute to improve the radiative recombination probability.

Topics
Doppler effect, Epitaxy, Scanning electron microscopy, Photoluminescence spectroscopy, Transmission electron microscopy, Photoluminescence decay, Radiative processes, Light emitting diodes, Quantum wells, Doping
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