Authors: Gonzalo, A; Utrilla, AD; Aeberhard, U; Braza, V; Reyes, DF; Marron, DF; Llorens, JM; Alen, B; Ben, T; Gonzalez, D; Guzman, A; Hierro, A; Ulloa, JM
Article.
Sol. Energy Mater. Sol. Cells. vol: 210. page: 0927-0248.
Date: JUN 15. 2020.
Doi: 10.1016/j.solmat.2020.110500.
Abstract:
We demonstrate type-II GaAsSb/GaAsN superlattices (SL) as a suitable structure to form the lattice-matched 1.0-1.15 eV subcell that would allow the implementation of the optimum monolithic multi-junction solar cell design. The separation of Sb and N atoms during growth leads to an improved composition homogeneity and a lower defect density than in the bulk GaAsSbN counterparts. The type-II band alignment SLs provide long radiative lifetimes that facilitate carrier collection as compared to equivalent type-I SLs. Moreover, the radiative lifetime can be controllably tuned through the period thickness, which is not possible in type-I SLs. A reduced period thickness results in enhanced absorption due to increased wavefunction overlap, as well as in a change in the transport regime from diffusive to quasiballistic, providing improved carrier extraction efficiency. As a result, the short period SL single junction solar cells show an enhanced power conversion efficiency of 134% over the equivalent bulk devices..
