Great emission enhancement and excitonic recombination dynamics of InGaN/GaN nanorod structures

Excitonic recombination dynamics has been investigated on a series of InxGa(1-x)N/GaN (0.10 <= x <= 0.30) nanorod (NR) structures with a diameter of similar to 220 nm by time-revolved photoluminescence (PL). The NR structures are fabricated by means of a post-growth etching technique. Compared with their corresponding as-grown samples, the time-integrated PL intensities of the NR samples show a remarkable enhancement with a factor of up to 52 at room temperature. The ratios of the radiative to non-radiative recombination lifetime of the NR structures are much less sensitive to temperature than those of their corresponding as-grown samples. This becomes more prominent with increasing indium composition. A distinct delay in transition temperature, where the dominating emission mechanism changes from radiative to non-radiative recombination, has been observed on the NR structures. The great enhancement in optical properties is attributed to both strain relaxation and extra in-plane excitonic confinement due to the nanostructures. (C) 2013 AIP Publishing LLC.