Title :
Moving past 2.0eV: Engineered ZnSe-GaAs alloys for multijunction solar cells
Author :
Montgomery, Kyle H. ; Woodall, Jerry M.
Author_Institution :
Birck Nanotechnol. Center, Purdue Univ., West Lafayette, IN, USA
Abstract :
The heterovalent quaternary ZnSe-GaAs is proposed for use in next generation multijunction solar cells due to its wide range of direct band gaps (1.42 to 2.67eV) and lattice-match with GaAs. A top subcell with band gap around 2eV is needed for optimal 3-junction cells with a fixed GaAs middle cell (one sun efficiency of 44.8% for current matched conditions and 45.8% without current matching). In 4-junction designs, the top cell needs to have a band gap around 2.4eV with fixed GaInP (EG = 1.89eV) and GaAs middle cells (one sun efficiency of 40.1% for current-matched conditions and 49.1% without current matching). We have simulated a “practical” cell with a (ZnSe)x(GaAs)1-x base layer with a band gap of 2.33eV. Assuming short non-radiative lifetimes and relatively low mobilities, a single cell efficiency of 11.4% with open circuit voltage of 1.94V and short circuit current of 6.5mA/cm2 can be attained, which is >70% of the theoretical max.
Keywords :
II-VI semiconductors; III-V semiconductors; energy gap; gallium arsenide; semiconductor junctions; short-circuit currents; solar cells; zinc alloys; zinc compounds; ZnSe-GaAs; direct band gaps; next generation multijunction solar cells; open circuit voltage; optimal 3-junction cells; short circuit current; short nonradiative lifetimes; single cell efficiency; voltage 1.94 V; voltage 2.0 EV; voltage 2.33 EV; voltage 2.4 EV; Gallium arsenide; Junctions; Metals; Photonic band gap; Photovoltaic cells; Solids;
Conference_Titel :
Photovoltaic Specialists Conference (PVSC), 2010 35th IEEE
Conference_Location :
Honolulu, HI
Print_ISBN :
978-1-4244-5890-5
DOI :
10.1109/PVSC.2010.5617175
