Optical microprism cavities based on dislocation-free GaN

Three-dimensional growth of nanostructures can be used to reduce the threading dislocation density that degrades III-nitride laser performance. Here, nanowire-based hexagonal GaN microprisms with flat top and bottom c-facets are embedded between two dielectric distributed Bragg reflectors to create...

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Bibliographic Details
Published in:Applied physics letters 2020-12, Vol.117 (23)
Main Authors: Hjort, Filip, Khalilian, Maryam, Bengtsson, Jörgen, Bengths, Marcus, Gustavsson, Johan, Gustafsson, Anders, Samuelson, Lars, Haglund, Åsa
Format: Article
Language:English
Subjects:
Applied physics
Atom and Molecular Physics and Optics
Atom- och molekylfysik och optik
Bragg reflectors
Condensed Matter Physics
Den kondenserade materiens fysik
Dislocation density
Electron beams
Finite element method
Fysik
Gallium nitrides
Holes
Nanowires
Natural Sciences
Naturvetenskap
Physical Sciences
Prisms
Q factors
Threading dislocations
Threshold currents
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Summary:Three-dimensional growth of nanostructures can be used to reduce the threading dislocation density that degrades III-nitride laser performance. Here, nanowire-based hexagonal GaN microprisms with flat top and bottom c-facets are embedded between two dielectric distributed Bragg reflectors to create dislocation-free vertical optical cavities. The cavities are electron beam pumped, and the quality (Q) factor is deduced from the cavity-filtered yellow luminescence. The Q factor is ∼500 for a 1000 nm wide prism cavity and only ∼60 for a 600 nm wide cavity, showing the strong decrease in Q factor when diffraction losses become dominant. Measured Q factors are in good agreement with those obtained from quasi-3D finite element frequency-domain method and 3D beam propagation method simulations. Simulations further predict that a prism cavity with a 1000 nm width will have a Q factor of around 2000 in the blue spectral regime, which would be the target regime for real devices. These results demonstrate the potential of GaN prisms as a scalable platform for realizing small footprint lasers with low threshold currents.
ISSN:0003-6951
1077-3118
1077-3118
DOI:10.1063/5.0032967