Title :
Quantum confined electronic states in InGaN dots embedded in GaN: tight-binding calculation
Author :
Saito, T. ; Arakawa, Y.
Author_Institution :
Center for Collaborative Res., Tokyo Univ., Japan
Abstract :
We have calculated the electronic states of In0.2Ga0.8N hexagonal quantum dots (QDs) embedded in a GaN barrier layer using a valence-force-field method and an sp3 tight-binding method. Assuming no polarization field, the energy gap is calculated to be 2.710 eV for the QD with diameter of 86.4 Å and height of 20.8 Å. The electron wave functions confined in the QD exhibit atomic scale fluctuation due to the alloy disorder. Including the piezoelectric polarization, we have found that the nonuniform polarization field is induced in the QD; 2.51 MV/cm at the dot center. Under the field, the energy gap is 2.502 eV (decreases by 0.208 eV). The energy separation between the ground and next excited levels of electron is 63.6 meV, which is large enough for application to the QD laser
Keywords :
III-V semiconductors; energy gap; gallium compounds; indium compounds; semiconductor quantum dots; tight-binding calculations; wave functions; GaN barrier layer; In0.2Ga0.8N-GaN; alloy disorder; confined electronic states; electron wave functions; energy gap; hexagonal quantum dots; piezoelectric polarization; sp3 tight-binding method; valence-force-field method; Atomic layer deposition; Bonding; Capacitive sensors; Electrons; Gallium nitride; Piezoelectric polarization; Potential well; Quantum dot lasers; Quantum dots; US Department of Transportation;
Conference_Titel :
Compound Semiconductors, 2000 IEEE International Symposium on
Conference_Location :
Monterey, CA
Print_ISBN :
0-7803-6258-6
DOI :
10.1109/ISCS.2000.947170
