Title :
Simulation of optical properties of Si wire cells
Author :
Altermatt, Pietro P. ; Yang, Yang ; Langer, T. ; Schenk, Andreas ; Brendel, Rolf
Author_Institution :
Dep. Solar Energy, Leibniz Univ. of Hannover, Hannover, Germany
Abstract :
We solve the Maxwell equations to quantify the amount of photo-generation in Si solar cells consisting of arrays of wires instead of bulk thin-films. Published transmission and reflectance measurements suggest that an array of Si wires absorbs sunlight very effectively due to strong diffraction and scattering. However, a detailed theoretical understanding and quantification of the actual photo-generation is only in its initial stage. In our simulations, the geometrical parameters of the wires are synthesized by means of cluster simulations. Applying the finite element method, we are able to compute randomly aligned wires within manageable time limits and affordable computer capacity. We show that Si wires have strong photonic properties. For example, our simulations surpass the Lambertian limit (for isotropically incident light) at ¿ = 1000 nm, as has been reported in many experiments.
Keywords :
Maxwell equations; elemental semiconductors; finite element analysis; semiconductor device measurement; semiconductor device models; silicon; solar cell arrays; Lambertian limit; Maxwell equations; Si; cluster simulations; finite element method; photo-generation; randomly aligned wires; reflectance measurement; solar cells; transmission measurement; wavelength 1000 nm; wire arrays; wire cells; wire geometrical parameters; Computational modeling; Light scattering; Maxwell equations; Optical diffraction; Optical scattering; Photovoltaic cells; Reflectivity; Semiconductor thin films; Solid modeling; Wire;
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.2009.5411125
