Strain-Induced Band Gap Variation in InGaN/GaN Short Period Superlattices

Abstract: The use of strained substrates may overcome indium incorporation limits without inducing plastic relaxation in InGaN quantum wells, and this is particularly important for short-period InGaN/GaN superlattices. By incorporating elastic strain into these heterostructures, their optoelectronic behavior is modified. Our study employed density functional theory calculations to investigate the variation in the band-gap energy of short-period InGaN/GaN superlattices that comprise pseudomorphic quantum wells with a thi… Show more

“…We evaluated the evolution of the electronic band gap by introducing a biaxial tensile strain, as experimentally reported for GaN grown on sapphire. ,, Eight different biaxial strains up to 1.01% were evaluated, and in this range, we observed a perfect linear correlation between the band gap and the induced strain (see Figure S4). A theoretical band gap of 3.27 eV was obtained which is in excellent agreement with other theoretical studies. − The observed changes in band gap are in line with previous studies reported by Chatzopoulou et al in which E g decreased 5.4% (3.28 to ∼3.1 eV) when applying a 1.5% biaxial strain. In comparison, we observed a reduction of 7.4% for a similar biaxial strain.…”

“…A theoretical band gap of 3.27 eV was obtained which is in excellent agreement with other theoretical studies. 35−37 The observed changes in band gap are in line with previous studies reported by Chatzopoulou et al 38 in which E g decreased 5.4% (3.28 to ∼3.1 eV) when applying a 1.5% biaxial strain. In comparison, we observed a reduction of 7.4% for a similar biaxial strain.…”

Electronic Properties of Hexagonal V-Shaped Gallium Nitride Pits

“…We evaluated the evolution of the electronic band gap by introducing a biaxial tensile strain, as experimentally reported for GaN grown on sapphire. ,, Eight different biaxial strains up to 1.01% were evaluated, and in this range, we observed a perfect linear correlation between the band gap and the induced strain (see Figure S4). A theoretical band gap of 3.27 eV was obtained which is in excellent agreement with other theoretical studies. − The observed changes in band gap are in line with previous studies reported by Chatzopoulou et al in which E g decreased 5.4% (3.28 to ∼3.1 eV) when applying a 1.5% biaxial strain. In comparison, we observed a reduction of 7.4% for a similar biaxial strain.…”

“…A theoretical band gap of 3.27 eV was obtained which is in excellent agreement with other theoretical studies. 35−37 The observed changes in band gap are in line with previous studies reported by Chatzopoulou et al 38 in which E g decreased 5.4% (3.28 to ∼3.1 eV) when applying a 1.5% biaxial strain. In comparison, we observed a reduction of 7.4% for a similar biaxial strain.…”

Electronic Properties of Hexagonal V-Shaped Gallium Nitride Pits

Recent progress of indium-bearing group-III nitrides and devices: a review

Unraveling the composition of monolayer-thick InGaN/GaN quantum wells: A quantitative analysis via probe-corrected HRSTEM