Emission wavelength red-shift by using “semi-bulk” InGaN buffer layer in InGaN/InGaN multiple-quantum-well
Auteurs | Alam S., Sundaram S., Li X., El Gmili Y., Elouneg-Jamroz M., Robin I.C., Patriarche G., Salvestrini J.-P., Voss P.L., Ougazzaden A. |
Year | 2017-0488 |
Source-Title | Superlattices and Microstructures |
Affiliations | School of Electrical and Computer Engineering, Georgia Institute of Technology, Atlanta, GA, United States, Georgia Tech-CNRS, UMI 2958, Metz, France, CEA-LETI, Minatec Campus, Grenoble, France, LMOPS, University of Lorraine, EA4423, Metz, France, Laboratory for Photonics and Nanostructures, CNRS, Route de Nozay, Marcoussis, France |
Abstract | We report an elongation of emission wavelength by inserting a ?70 nm thick high quality semi-bulk (SB) InyGa1-yN buffer layer underneath the InxGa1-xN/InyGa1-yN (x >, y) multi-quantum-well (MQW).While the MQW structure without the InGaN SB buffer is fully strained on the n-GaN template, the MQW structure with the buffer has ?15% relaxation. This small relaxation along with slight compositional pulling induced well thickness increase of MQW is believed to be the reason for the red-shift of emission wavelength. In addition, the SB InGaN buffer acts as an electron reservoir and also helps to reduce the Quantum Confined Stark Effect (QCSE) and thus increase the emission intensity. In this way, by avoiding fully relaxed buffer induced material degradation, a longer emission wavelength can be achieved by just using InGaN SB buffer while keeping all other growth conditions the same as the reference structure. Thus, a reasonably thick fully strained or very little relaxed InGaN buffer, which is realized by “semi-bulk” approach to maintain good InGaN material quality, can be beneficial for realizing LEDs, grown on top of this buffer, emitting in the blue to cyan to green regime without using excess indium (In). © 2017 Elsevier Ltd |
Author-Keywords | Green-gap, InGaN buffer, InGaN multi-quantum-well, LED, MOVPE |
Index-Keywords | Buffer layers, Doppler effect, Light emitting diodes, Metallorganic vapor phase epitaxy, Semiconducting indium compounds, Telecommunication repeaters, Electron reservoir, Emission wavelength, Green-gap, InGaN buffer, InGaN buffer layer, Material degradation, Multi quantum wells, Quantum-confined Stark effect, Semiconductor quantum wells |
ISSN | 7496036 |
Lien vers article | Link |