Abstract
Conventional c-plane wurtzite InGaN/GaN quantum wells are subject to a large internal field that acts to separate electrons
and holes and thereby lowers the rate of radiative recombination. This effect is exacerbated for higher indium contents and
so may contribute to the lower efficiency of c-plane wurtzite InGaN/GaN QWs when emitting at green and amber
wavelengths. In comparison, InGaN/GaN QWs grown in the cubic zincblende phase along the (001) direction are free of
such fields and so exhibit recombination lifetimes that are shorter by two orders of magnitude and independent of indium
content. Here, we report on zincblende QWs grown by metal-organic chemical vapor deposition at different temperatures.
This results in different indium contents and thereby allows tuning of the emission band from blue to yellow. For each
indium content, the spectrally integrated emission quenches as the temperature rises. However, the ratio of room
temperature to low temperature emission improves for higher indium contents, increasing from 18 % to 34 % as the
emission peak is tuned from 2.8 eV to 2.1 eV. This behavior is attributed to the thermal escape of carriers from the QWs
playing an important role in the temperature dependent quenching of emission
and holes and thereby lowers the rate of radiative recombination. This effect is exacerbated for higher indium contents and
so may contribute to the lower efficiency of c-plane wurtzite InGaN/GaN QWs when emitting at green and amber
wavelengths. In comparison, InGaN/GaN QWs grown in the cubic zincblende phase along the (001) direction are free of
such fields and so exhibit recombination lifetimes that are shorter by two orders of magnitude and independent of indium
content. Here, we report on zincblende QWs grown by metal-organic chemical vapor deposition at different temperatures.
This results in different indium contents and thereby allows tuning of the emission band from blue to yellow. For each
indium content, the spectrally integrated emission quenches as the temperature rises. However, the ratio of room
temperature to low temperature emission improves for higher indium contents, increasing from 18 % to 34 % as the
emission peak is tuned from 2.8 eV to 2.1 eV. This behavior is attributed to the thermal escape of carriers from the QWs
playing an important role in the temperature dependent quenching of emission
| Original language | English |
|---|---|
| Title of host publication | Proceedings |
| Publisher | SPIE |
| Pages | 1336605-1 |
| Number of pages | 1336605 |
| Volume | 13366 |
| DOIs | |
| Publication status | Published - 19 Mar 2025 |
Keywords
- quantum wells
- zincblende
- InGaN/GaN
Research Beacons, Institutes and Platforms
- Photon Science Institute