Title :
Band gap engineering of (InGaN) for photovoltaic application
Author :
Salmani, E. ; Marjaoui, A. ; Mounkachi, O. ; Ben Ali, M. ; El Moussaoui, H. ; Ez-Zahraouy, H. ; Hamedoun, M. ; Benaissa, M. ; Benyoussef, A.
Author_Institution :
Inst. for Nanomater. & Nanotechnol., MAScIR, Rabat, Morocco
Abstract :
Due to their technological application, a precise prediction of the optical properties of III-nitride alloys is significantly attractive. Numerical simulation based on first-principles calculations is applied to study the structural characteristics and band-energy properties of the zincblende Ga1-xInxN. The purpose of this study is to explore theoretically the electronic and optical characteristics of the parent InN and GaN compounds and their ternary alloys by utilizing KKR-CPA approach. We show that density functional theory is a very powerful tool for: 1- studying the local doping effects, 2- defects effect, 3- size and disorder effect on optical and electronic properties of these materials, 4- predicting properties of new materials.
Keywords :
CPA calculations; III-V semiconductors; KKR calculations; ab initio calculations; density functional theory; energy gap; gallium compounds; indium compounds; numerical analysis; size effect; solar cells; wide band gap semiconductors; GaN compound; III-nitride alloys; InGaN; InN compound; KKR-CPA approach; band gap engineering; band-energy properties; defect effect; density functional theory; disorder effect; electronic characteristics; first-principles calculations; local doping effects; numerical simulation; optical properties; photovoltaic application; size effect; structural characteristics; ternary alloys; Approximation methods; Atomic layer deposition; Gallium nitride; Nanostructured materials; Photonics; Semiconductor diodes; Density functional theory; Gallium Nitride; Photovoltaic application;
Conference_Titel :
Renewable and Sustainable Energy Conference (IRSEC), 2014 International
Print_ISBN :
978-1-4799-7335-4
DOI :
10.1109/IRSEC.2014.7059771
