Title :
Numerical Simulation of Light-Trapping and Photoelectric Conversion in Single Nanowire Silicon Solar Cells
Author :
Yaohui Zhan ; Xiaofeng Li ; Yao Li
Author_Institution :
Center for Composite Mater., Harbin Inst. of Technol., Harbin, China
Abstract :
Single nanowire solar cells (SNSCs) are typical nanoscale optoelectronic devices with unique photonic and electronic properties, which require precise designs in terms of a comprehensive simulation technique. We present a coupled model for silicon-based SNSCs which solves both Maxwell and semiconductor equations self-consistently using the finite-element method. The light-trapping behavior (e.g., leaky-mode resonances) and carrier generation/recombination inside the nanowire cavity are simulated and analyzed especially by addressing the effects of semiconductor doping, surface recombination, and device dimension on the performance of the solar cells. The absorption efficiency, external quantum efficiency, and current-voltage characteristics have been obtained for a complete evaluation of SNSCs.
Keywords :
Maxwell equations; elemental semiconductors; finite element analysis; nanowires; photoelectricity; silicon; solar cells; surface recombination; Maxwell equation; Si; absorption efficiency; carrier generation; carrier recombination; coupled model; current-voltage characteristics; electronic properties; external quantum efficiency; finite-element method; light trapping; nanoscale optoelectronic device; nanowire cavity; photoelectric conversion; photonic properties; semiconductor doping; semiconductor equation; single nanowire silicon solar cells; surface recombination; Charge carrier processes; Doping; Mathematical model; Nanoscale devices; Photovoltaic cells; Spontaneous emission; Light trapping; nanoelectronic devices; photon and carrier transports; single nanowire solar cells (SNSCs);
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2013.2246771
