Title :
Tunneling through GaAs-Ge superlattices for high efficiency solar cells
Author :
Varonides, A.C. ; Spallet, R.A.
Author_Institution :
Univ. of Scranton, Scranton, PA, USA
Abstract :
Tunneling currents in superlattice-based solar cells for high efficiency are major conduction mechanism in addition to thermal carrier escape. We propose a model for GaAs/Ge mqw structures, through which, tunneling current can be found as function of device geometry (quantum well and barrier width) Fermi energy and conduction band offset. Our model is adoptable to any mqw structure in the intrinsic region of pin solar cells. High short circuit currents are computed based on a tunneling model that includes device parameters, solar photon incidence and open circuit voltage. Under one sun, and at room temperatures, we predict tunneling currents in excess of 30mA/cm2 for GaAs-Ge multijunction mid region of pin III-V solar cell structure. The total unit (top and bottom cell) is a high efficiency solar cell (in excess of 40%) with a 28% top cell and a 22% bottom cell.
Keywords :
Fermi level; III-V semiconductors; conduction bands; elemental semiconductors; gallium arsenide; germanium; semiconductor quantum wells; solar cells; tunnelling; Fermi energy; GaAs-Ge; barrier width; conduction band offset; conduction mechanism; device geometry; open circuit voltage; pin III-V solar cell; pin solar cells; quantum well; short circuit currents; solar photon incidence; superlattice-based solar cells; temperature 293 K to 298 K; thermal carrier escape; tunneling currents; Gallium arsenide; Geometry; Optical computing; Photovoltaic cells; Quantum well devices; Short circuit currents; Solid modeling; Superlattices; Thermal conductivity; Tunneling;
Conference_Titel :
Photovoltaic Specialists Conference (PVSC), 2009 34th IEEE
Conference_Location :
Philadelphia, PA
Print_ISBN :
978-1-4244-2949-3
Electronic_ISBN :
0160-8371
DOI :
10.1109/PVSC.2009.5411469
