Title :
Decreasing dark current in long wavelength InAs/GaSb thermophotovoltaics via bandgap engineering
Author :
Licht, Abigail S. ; DeMeo, Dante F. ; Rodriguez, J.B. ; Vandervelde, Thomas E.
Author_Institution :
Renewable Energy & Appl. Photonics Labs., Tufts Univ., Medford, MA, USA
Abstract :
At present, the state of the art thermophotovoltaic diode material is GaSb, with a bandgap of 0.7 eV corresponding to source temperatures greater than 1000°C. We investigate alternative bandstructure designs using the InAs/GaSb superlattice material system, which enable shorter bandgaps corresponding to lower source temperatures. For an InAs/GaSb superlattice system, we examine the effect of a monovalent barrier inserted between the p and n-doped regions. Through simulations, with the program Silvaco, we demonstrate that this barrier decreases the dark current and increases the open-circuit voltage, improving the overall power output and, thus, extending the operational wavelength of thermophotovoltaics.
Keywords :
band structure; gallium compounds; indium compounds; semiconductor superlattices; thermophotovoltaic cells; InAs-GaSb; Silvaco program; bandstructure designs; decreasing dark current; electron volt energy 0.7 eV; long wavelength thermophotovoltaics; monovalent barrier; n-doped regions; open-circuit voltage; p-doped regions; source temperatures; superlattice material system; thermophotovoltaic diode material; Dark current; Photonic band gap; Semiconductor diodes; Superlattices; Temperature; Thermophotovoltaics; bariode; infrared; monovalent; superlattice;
Conference_Titel :
Photovoltaic Specialist Conference (PVSC), 2014 IEEE 40th
Conference_Location :
Denver, CO
DOI :
10.1109/PVSC.2014.6924964
