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Innovative structures for thin film crystalline silicon solar cells to give high efficiencies from low quality silicon

Authors

Alistair B. Sproul, Sean Edmiston, Stuart R. Wenham, Gernot Heiser and Martin A. Green

    School of Computer Science and Engineering
    UNSW,
    Sydney 2052, Australia

Abstract

The multilayer cell has been specifically designed with the aim to obtain high solar cell efficiency using low quality, thin film, polycrystalline silicon material. The structure consists of multiple p- and n-type silicon layers. This paper examines the tolerance of the cell design to a range of metallic impurities and grain boundaries using computer simulations. The modelled results indicate that the device can tolerate impurity concentrations up to 250 times greater than a conventional, thick solar cell. Further, the results indicate that the structure has excellent tolerance to grain boundaries present in bulk regions of the device. The simulations indicate that grain boundaries present in depletion regions will limit efficiencies considerably if the effective recombination velocity of the grain boundary approaches 107 cm/s. This extreme case should be largely avoided utilizing grain boundary passivation techniques during device fabrication.

BibTeX Entry

  @inproceedings{Sproul_EWHG_94,
    title            = {Innovative Structures for Thin Film Crystalline Silicon Solar Cells to Give High Efficiencies from
                        Low Quality Silicon},
    author           = {Alistair B. Sproul and Sean Edmiston and Stuart R. Wenham and Gernot Heiser and Martin A. Green},
    month            = dec,
    year             = {1994},
    organization     = {IEEE},
    booktitle        = {1st World Conference on Photovoltaic Energy Conversion},
    pages            = {1563--1566},
    address          = {Waikoloa, HI, USA}
  }

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