Title :
Drift-Diffusion Modeling for Impurity Photovoltaic Devices
Author :
Lin, Albert S. ; Phillips, Jamie D.
Author_Institution :
Univ. of Michigan, Ann Arbor, MI, USA
Abstract :
A 1-D drift-diffusion modeling for impurity photovoltaics is presented. The model is based on the self-consistent solution of Poisson´s equation and carrier continuity equations incorporating generation and recombination mechanisms including the intermediate states. The model is applied to a prototypical solar cell device, where strong space charge effects and reduced conversion efficiency are identified for the case of lightly doped absorption regions. A doping compensation scheme is proposed to mitigate the space charge effects, with optimal doping corresponding to one-half the concentration of the intermediate states. The compensated doping device design provides calculated conversion efficiencies of approximately 40%, which is similar to the maximum expected values from prior 0-D models. The carrier transport between intermediate levels is shown to be noncritical for achieving the efficiency limit predicted by 0-D models. The qualitative behavior of the model is compared to existing experimental data on quantum dot solar cells.
Keywords :
Poisson equation; doping; impurities; photovoltaic cells; solar cells; 1D drift diffusion modeling; Poisson equation; carrier continuity equation; carrier transport; compensated doping device design; conversion efficiency; doped absorption region; doping compensation; impurity photovoltaic device; optimal doping; prototypical solar cell device; quantum dot solar cells; recombination mechanism; space charge effects; Doping; Impurities; Photovoltaic cells; Photovoltaic systems; Poisson equations; Prototypes; Radiative recombination; Semiconductor process modeling; Solar power generation; Space charge; Drift-diffusion model; intermediate levels (ILs); semiconductor; solar cell;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2009.2032741
