Reducing threading dislocation density in GaSb photovoltaic devices on GaAs by using AlSb dislocation filtering layers

GaSb based photovoltaic devices have been demonstrated on GaAs substrates by inducing interfacial array of 90° misfit dislocations. Despite the beneficial qualities of the highly stable 90° misfit dislocation, there is a significant density of residual threading dislocations in the GaSb layer, resul...

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Bibliographic Details
Published in:Solar energy materials and solar cells 2018-10, Vol.185 (C), p.21-27
Main Authors: Mansoori, A., Addamane, S.J., Renteria, E.J., Shima, D.M., Behzadirad, M., Vadiee, E., Honsberg, C., Balakrishnan, G.
Format: Article
Language:English
Subjects:
Density
Dislocation
Dislocation density
Electric power
Filtration
Gallium antimonides
GaSb
Lattice matching
Optimization
Photovoltaic cells
Photovoltaics
Recombination
Solar cell
Solar cells
Solar energy
Substrates
Temperature
Thermophotovoltaic cell
Threading dislocation density
Threading dislocations
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Summary:GaSb based photovoltaic devices have been demonstrated on GaAs substrates by inducing interfacial array of 90° misfit dislocations. Despite the beneficial qualities of the highly stable 90° misfit dislocation, there is a significant density of residual threading dislocations in the GaSb layer, resulting in the degradation of the electrical performance of such photovoltaic cells compared to lattice matched devices. We aim to reduce threading dislocation density by optimizing growth temperature and by using an AlSb dislocation filtering layer. The growth temperature optimization results in a reduction of the threading dislocation density to 1.3 × 108 cm−2. Adding an AlSb dislocation filtering layer further improves the electrical performance of the GaSb solar cells by reducing the threading dislocation density to 4 × 107 cm−2. A comparison between the experimental data and theoretical calculation confirms that the recombination in dislocation centers is a dominant loss mechanism in GaSb solar cell grown on GaAs substrate.
ISSN:0927-0248
1879-3398
DOI:10.1016/j.solmat.2018.05.008