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  Gabriel, O.; Frijnts, T.; Preissler, N.; Amkreutz, D.; Calnan, S.; Ring, S.; Stannowski, B.; Rech, B.; Schlatmann, R.: Crystalline silicon on glass - interface passivation and absorber material quality. Progress in Photovoltaics 24 (2016), p. 1499-1512

10.1002/pip.2707

Abstract:
Thin crystalline silicon solar cells prepared directly on glass substrates by means of liquid-phase crystallization of the absorber utilize only a small fraction of the silicon material used by standard wafer-based silicon solar cells. The material consists of large crystal grains of up to square centimeter area and results in solar cells with open-circuit voltages of 650 mV, which is comparable with results achieved with multi-crystalline silicon wafers. We give a brief status update and present new results on the electronic interface and bulk properties. The interrelation between surface passivation and additional hydrogen plasma passivation is investigated for p-type and n-type absorbers with different doping concentrations. Internal quantum efficiency measurements from both sides on bifacial solar cells are used to extract the bulk-diffusion length and surface-recombination velocity. Finally, we compare various types of solar cell devices based on 10 µm thin crystalline silicon, where conversion efficiencies of 11–12% were achieved with p–type and n-type liquid-phase crystallized absorbers on glass.