Title :
Auger Recombination in Luminescent, CMOS-compatible Si Nanowires
Author :
Guichard, Alex R. ; Kekatpure, Rohan D. ; Brongersma, Mark L.
Author_Institution :
Geballe Lab. for Adv. Mater., Stanford Univ., Stanford, CA
Abstract :
Auger recombination is an important process limiting stimulated optical emission in many semiconductor systems as it is especially prevalent at high excitation intensities. We have quantified the Auger rate in TiSi2-catalyzed Si nanowires by determining an Auger coefficient from time-resolved photoluminescence (PL) data. Above a threshold excitation intensity, the PL decay lifetime at 1.55 eV (800 nm) shortens with increasing excitation, suggesting that Auger recombination is the dominant non-radiative process at high excitation. The determined Auger rates are greater than that for bulk, but an order of magnitude less than that measured for nanoparticles.
Keywords :
Auger effect; electron-hole recombination; elemental semiconductors; nanowires; photoluminescence; silicon; time resolved spectra; Auger coefficient; Auger recombination; CMOS-compatible nanowires; Si; decay lifetime; excitation intensities; excitation intensity; nonradiative process; semiconductor systems; stimulated optical emission; time-resolved photoluminescence; Absorption; Charge carrier processes; Crystalline materials; Crystallization; Excitons; Luminescence; Nanoparticles; Nanowires; Radiative recombination; Spontaneous emission;
Conference_Titel :
Group IV Photonics, 2007 4th IEEE International Conference on
Conference_Location :
Tokyo
Print_ISBN :
978-1-4244-0934-1
DOI :
10.1109/GROUP4.2007.4347733
