Room-temperature 1.54 μm electroluminescence from Er-doped silicon-rich silicon oxide films deposited on n+-Si substrates by magnetron sputtering

Room-temperature 1.54 mum electroluminescence (EL) was compared for Au/SiO2:Er/n(+)-Si and Au/SiOx:Si:Er/n(+)-Si diodes under reverse bias. The 18 nm thick SiO2:Er and SiOx:Si:Er films were deposited by the magnetron sputtering technique. The maximum of the EL intensity was reached after annealing at 900 degreesC (SiO2:Er) and 800 degreesC (SiOx:Si:Er). The threshold potential of the EL was about 4 and 6 V for the Au/SiOx:Si:Er/n(+)-Si and Au/SiO2:Er/n(+)-Si diodes, respectively. The power efficiency was larger for the Au/SiOx:Si:Er/n(+)-Si diode than that for the Au/SiO2:Er/n(+)-Si diode by six times. Our experimental results demonstrate that the existence of Si nanoclusters reduces the threshold potentials of the EL and strongly enhances the power efficiency for Er3+ EL. (C) 2001 American Institute of Physics.

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