Open AccessBelow-band-gap electroluminescence related to doping spikes in boron-implanted siliconp n
Author(s) -
Jiaming Sun,
T. Dekorsy,
W. Skorupa,
B. Schmidt,
A. Mücklich,
M. Helm
Publication year - 2004
Publication title -
physical review b
Language(s) - English
Resource type - Journals
eISSN - 1538-4489
pISSN - 1098-0121
DOI - 10.1103/physrevb.70.155316
Subject(s) - electroluminescence , doping , materials science , exciton , boron , luminescence , silicon , diode , photoluminescence , optoelectronics , binding energy , band gap , energy (signal processing) , light emitting diode , analytical chemistry (journal) , atomic physics , physics , condensed matter physics , nanotechnology , chemistry , nuclear physics , layer (electronics) , quantum mechanics , chromatography
The origin of two luminescence bands with maxima around 1.05 eV and 0.95 eV is studied in silicon pn diodes prepared by boron implantation. The two peaks are related to the formation of p-type doping spikes on a nanometer scale. These doping spikes are generated by long-time thermal activation of preformed boron clusters. The peak with a larger binding energy stems from spatially indirect excitons bound to doping spikes in a strained environment, while the peak with a lower binding energy is related to doping spikes without strain. The doping spikes are able to capture spatially indirect bound excitons with a low recombination rate, thus effectively suppressing the fast nonradiative recombination at defects. This effect leads to an efficient room temperature electroluminescence in silicon light-emitting diodes prepared by boron implantation.
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