Carrier localization due to statistical fluctuations in indium gallium nitride alloys has been recognized to play an important role for the performance of light-emitting diodes, both experimentally and through theoretical studies. While a random-alloy assumption is usually made, in this work we take into account the presence of spatial nonuniformities in the indium content on the nanometer scale and we theoretically analyze their impact on the electronic and optical properties of the alloy and the device. We show that indium clustering induces tail states in both the conduction and valence bands. This causes a reduction of the band gap and a broadening of the optical absorption edge. Furthermore, compositional fluctuations in the active region of the device determine a substantial broadening of the optical emission spectrum and a decrease of the peak emission energy, in agreement with experimental results. Moreover, the radiative recombination coefficient increases for an increasing degree of clustering, suggesting a transition to a quantum-dot-like structure. Finally, the temperature dependence of the radiative coefficient derived for the nonuniform structures is in good agreement with the experimental results, which show a temperature behavior opposite to the trend expected from standard theoretical considerations.
Impact of Compositional Nonuniformity in (In,Ga) N -Based Light-Emitting Diodes
Pecchia A;
2019
Abstract
Carrier localization due to statistical fluctuations in indium gallium nitride alloys has been recognized to play an important role for the performance of light-emitting diodes, both experimentally and through theoretical studies. While a random-alloy assumption is usually made, in this work we take into account the presence of spatial nonuniformities in the indium content on the nanometer scale and we theoretically analyze their impact on the electronic and optical properties of the alloy and the device. We show that indium clustering induces tail states in both the conduction and valence bands. This causes a reduction of the band gap and a broadening of the optical absorption edge. Furthermore, compositional fluctuations in the active region of the device determine a substantial broadening of the optical emission spectrum and a decrease of the peak emission energy, in agreement with experimental results. Moreover, the radiative recombination coefficient increases for an increasing degree of clustering, suggesting a transition to a quantum-dot-like structure. Finally, the temperature dependence of the radiative coefficient derived for the nonuniform structures is in good agreement with the experimental results, which show a temperature behavior opposite to the trend expected from standard theoretical considerations.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.