Silicon-Based Light-Emitting Devices: Properties and Applications of Crystalline, Amorphous and Er-Doped Nanoclusters

Author

Iacona, Fabio ; Irrera, Alessia ; Franzo, G. ; Pacifici, Domenico ; Crupi, Isodiana ; Miritello, Maria ; Presti, Calogero D. ; Priolo, Francesco

Author_Institution

Nat. Council of Res., Catania

Volume

12

Issue

6

fYear

2006

Firstpage

1596

Lastpage

1606

Abstract

In this paper, we summarize the results of an extensive investigation on the properties of MOS-type light-emitting devices based on silicon nanostructures. The performances of crystalline, amorphous, and Er-doped Si nanostructures are presented and compared. We show that all devices are extremely stable and robust, resulting in an intense room temperature electroluminescence (EL) at around 900 nm or at 1.54 mum. Amorphous nanoclusters are more conductive than the crystalline counterpart. In contrast, nonradiative processes seem to be more efficient for amorphous clusters resulting in a lower quantum efficiency. Erbium doping results in the presence of an intense EL at 1.54 mu m with a concomitant disappearance of the 900-nm emission. This suggests that under electrical pumping Er is excited through an efficient energy transfer from the silicon clusters which hence become dark. We have identified an Auger de-excitation of Er with trapped carriers as the main process competing with radiative emission and limiting EL efficiency. This process is particularly severe in presence of unbalanced carrier injection (electrons versus holes) and can be controlled in properly designed structures. These data are presented and their implications are discussed

Keywords

MIS devices; amorphous state; electroluminescence; elemental semiconductors; erbium; integrated optoelectronics; light emitting devices; nanostructured materials; semiconductor doping; silicon; 1.54 mum; 293 to 298 K; 900 nm; Auger deexcitation; Er-doped nanoclusters; Si:Er; amorphous nanoclusters; carrier injection; conductivity; crystalline nanoclusters; electrical pumping; electroluminescence; energy transfer; erbium doping; nonradiative process; quantum efficiency; radiative emission; room temperature; silicon clusters; silicon nanostructures; silicon-based light-emitting devices; trapped carriers; Amorphous materials; Crystallization; Doping; Electroluminescent devices; Erbium; Nanoscale devices; Nanostructures; Robustness; Silicon; Temperature; Electroluminescence (EL); electroluminescent devices; erbium; integrated optoelectronics; light-emitting devices; nanocrystals; optical interconnections;

fLanguage

English

Journal_Title

Selected Topics in Quantum Electronics, IEEE Journal of

Publisher

ieee

ISSN

1077-260X

Type

jour

DOI

10.1109/JSTQE.2006.880605

Filename

4032657