Title :
Room-Temperature Electroluminescence From GeSn Light-Emitting Pin Diodes on Si
Author :
Oehme, M. ; Werner, J. ; Gollhofer, M. ; Schmid, M. ; Kaschel, M. ; Kasper, E. ; Schulze, J.
Author_Institution :
Inst. for Semicond. Eng., Univ. of Stuttgart, Stuttgart, Germany
Abstract :
In this letter, a GeSn light-emitting pin diode integrated on Si via a Ge buffer is demonstrated and it is compared with a light-emitting pin diode made from pure, unstrained Ge on Si. The diode layer structures are grown with a special low-temperature molecular beam epitaxy process. The pseudomorphic GeSn layers (1.1% Sn content) on the Ge buffer are compressively strained. Both light-emitting pin diodes clearly show direct bandgap electroluminescence emission at room temperature. The electroluminescence peak of the GeSn light-emitting pin diode is shifted by 20 meV into the infrared region compared to the electroluminescence peak of the unstrained Ge light-emitting pin diode. The shift is due to the lower bandgap of GeSn and the influence of strain.
Keywords :
electroluminescence; elemental semiconductors; germanium compounds; infrared spectra; light emitting diodes; molecular beam epitaxial growth; p-i-n diodes; silicon; Ge buffer; GeSn; GeSn light-emitting pin diodes; Si; diode layer structures; electroluminescence emission; infrared region; molecular beam epitaxy process; pseudomorphic GeSn layers; silicon; Electroluminescence; Light emitting diodes; Molecular beam epitaxial growth; PIN photodiodes; Silicon; Tin; Electroluminescence; GeSn; Si photonics; germanium; light-emitting diode (LED);
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2011.2169052
