EPJ Photovoltaics (Jan 2013)

Performance potential of low-defect density silicon thin-film solar cells obtained by electron beam evaporation and laser crystallisation

  • Kim K. H.,
  • Egan R.,
  • Schubert U.,
  • Huang J.,
  • Kunz O.,
  • Ong D.,
  • Eggleston B.,
  • Evans R.,
  • Varlamov S.,
  • Dore J.,
  • Green M.

DOI
https://doi.org/10.1051/epjpv/2012012
Journal volume & issue
Vol. 4
p. 40301

Abstract

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A few microns thick silicon films on glass coated with a dielectric intermediate layer can be crystallised by a single pass of a line-focused diode laser beam. Under favorable process conditions relatively large linear grains with low defect density are formed. Most grain boundaries are defect-free low-energy twin-boundaries. Boron-doped laser crystallised films are processed into solar cells by diffusing an emitter from a phosphorous spin-on-dopant source, measuring up to 539 mV open-circuit voltage prior to metallisation. After applying a point-contact metallisation the best cell achieves 7.8% energy conversion efficiency, open-circuit voltage of 526 mV and short-circuit current of 26 mA/cm2. The efficiency is significantly limited by a low fill-factor of 56% due to the simplified metallisation approach. The internal quantum efficiency of laser crystallised cells is consistent with low front surface recombination. By improving cell metallisation and enhancing light-trapping the efficiencies of above 13% can be achieved.