Journal
SOLAR ENERGY MATERIALS AND SOLAR CELLS
Volume 235, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.solmat.2021.111467
Keywords
Auger recombination; Charge carrier lifetime; Silicon; Single-junction maximum efficiency; Intrinsic recombination; Parameterisation
Ask authors/readers for more resources
This study characterizes and optimizes next-generation silicon solar cell concepts by accurately assessing intrinsic recombination in crystalline silicon. By fabricating high-quality silicon sample sets and considering reabsorption effects, the researchers were able to extract the lifetime limitation due to Auger recombination. The revised fundamental limiting power conversion efficiency for single-junction crystalline silicon solar cells provides greater accuracy and alignment with actual recombination processes in silicon-based photovoltaics.
Characterisation and optimization of next-generation silicon solar cell concepts rely on an accurate knowledge of intrinsic charge carrier recombination in crystalline silicon. Reports of measured lifetimes exceeding the previous accepted parameterisation of intrinsic recombination indicate an overestimation of this recombination in certain injection regimes and hence the need for revision. In this work, twelve high-quality silicon sample sets covering a wide doping range are fabricated using state-of-the-art processing routes in order to permit an accurate assessment of intrinsic recombination based on wafer thickness variation. Special care is taken to mitigate extrinsic recombination due to bulk contamination or at the wafer surfaces. The combination of the high-quality samples with refined sample characterisation and lifetime measurements enables a much higher level of accuracy to be achieved compared to previous studies. We observe that reabsorption of luminescence photons inside the sample must be accounted for to achieve a precise description of radiative recombination. With this effect taken into account, we extract the lifetime limitation due to Auger recombination. We find that the extracted Auger recombination rate can accurately be parameterized using a physically motivated equation based on Coulombenhanced Auger recombination for all doping and injection conditions relevant for silicon-based photovoltaics. The improved accuracy of data description obtained with the model suggests that our new parameterisation is more consistent with the actual recombination process than previous models. Due to notable changes in Auger recombination predicted for moderate injection, we further revise the fundamental limiting power conversion efficiency for a single-junction crystalline silicon solar cell to 29.4%, which is within 0.1%abs compared to other recent assessments.
Authors
I am an author on this paper
Click your name to claim this paper and add it to your profile.
Reviews
Recommended
No Data Available