Fabrication and properties of coherent-structure In-polarity InN/In{sub 0.7}Ga{sub 0.3}N multiquantum wells emitting at around 1.55 {mu}m
- Graduate Course of Electrical and Electronic Engineering, Chiba University, 1-33 Yayoi-cho, Inage-ku, Chiba, 263-8522 (Japan)
In-polarity InN/In{sub 0.7}Ga{sub 0.3}N multiquantum wells (MQWs) were fabricated on a thick In{sub 0.7}Ga{sub 0.3}N interlayer/Ga-polarity GaN template by radio-frequency plasma-assisted molecular beam epitaxy. We then investigated how the lattice relaxation and piezoelectric field in InN wells affect their structural and photoluminescence (PL) properties, respectively. It was found that the critical thickness of InN well on In{sub 0.7}Ga{sub 0.3}N barrier was about 1 nm. A clear PL peak shift from 1.40 to 1.95 {mu}m was observed depending on the InN well thickness from 0.7 to 2.0 nm. Correspondingly, PL-intensity reduction was also observed with increasing well thickness. No PL was observed for the sample with 4.1 nm thick InN wells. On the basis of theoretical estimation of transition energies in InN/In{sub 0.7}Ga{sub 0.3}N MQWs, it was confirmed that the quantum-confined Stark effect (QCSE) played an important role for both the observed PL peak shift and the decrease in intensity. The piezoelectric field in coherently grown InN wells was about 3 MV/cm but it was reduced to about 1-2 MV/cm for the samples with relaxed InN wells. It was confirmed that the InN wells must be thinner than the critical thickness (1 nm) in following two points: to reduce defects arising from lattice relaxation and to reduce QCSE leading to emission-peak redshift and a decrease in intensity.
- OSTI ID:
- 21064407
- Journal Information:
- Journal of Applied Physics, Journal Name: Journal of Applied Physics Journal Issue: 8 Vol. 102; ISSN JAPIAU; ISSN 0021-8979
- Country of Publication:
- United States
- Language:
- English
Similar Records
GaAs/AlGaAs distributed feedback structure with multiquantum well for surface-emitting laser
InP-based quantum well solar cells grown by chemical beam epitaxy