Light emission and charge trapping in Er-doped silicon dioxide films containing silicon nanocrystals

High quantum efficiency erbium doped silicon nanocluster (Si-NC:Er) light emitting diodes (LEDs) were grown by low-pressure chemical vapor deposition (LPCVD) in a complementary metal-oxide-semiconductor (CMOS) line. Erbium (Er) excitation mechanisms under direct current (DC) and bipolar pulsed electrical injection were studied in a broad range of excitation voltages and frequencies. Under DC excitation, Fowler-Nordheim tunneling of electrons is mediated by Er-related trap states and electroluminescence originates from impact excitation of Er ions. When the bipolar pulsed electrical injection is used, the electron transport and Er excitation mechanism change. Sequential injection of electrons and holes into silicon nanoclusters takes place and nonradiative energy transfer to Er ions is observed. This mechanism occurs in a range of lower driving voltages than those observed in DC and injection frequencies higher than the Er emission rate. V C 2012 American Institute of Physics. [http://dx

Section: A Direct Current Excitationsupporting

confidence: 69%

Bipolar pulsed excitation of erbium-doped nanosilicon light emitting diodes

Anopchenko

Tengattini

Marconi

et al. 2012

“…8 Because Si-ncls are capable of efficient energy transfer to erbium and other rare earth ions, silicon-rich erbiumdoped silica as a material for EL devices became a subject of research. [9][10][11] However, the role of the Si-ncls in the EL of Er and conduction mechanisms is not clear. It is agreed that the presence of Si-ncls introduces more efficient conduction mechanisms, including variable range hopping, 12 direct tunneling ͑DT͒, trap-assisted tunneling, Poole-Frenkel ͑PF͒ conduction, 13 or space charged limited current ͑SCLC͒.…”

Section: Introductionmentioning

confidence: 99%

“…11 Si nanoparticles favor the injection of charge carriers, improve device lifetime, 14 reduce the population of hot electrons, 15 and consequently reduce impact excitation of Er. 10,16 It has also been argued that other mechanisms of EL can be introduced, including energy transfer from electrically excited Sincls to erbium ions. 13 In general, different processes can be dominant depending on material composition, film thickness, or voltage regimes.…”

Section: Introductionmentioning

confidence: 99%

Current transport and electroluminescence mechanisms in thin SiO2 films containing Si nanocluster-sensitized erbium ions

Jambois

Berencén

Hijazi

et al. 2009

We have studied the current transport and electroluminescence properties of metal oxide semiconductor ͑MOS͒ devices in which the oxide layer, which is codoped with silicon nanoclusters and erbium ions, is made by magnetron sputtering. Electrical measurements have allowed us to identify a Poole-Frenkel conduction mechanism. We observe an important contribution of the Si nanoclusters to the conduction in silicon oxide films, and no evidence of Fowler-Nordheim tunneling. The results suggest that the electroluminescence of the erbium ions in these layers is generated by energy transfer from the Si nanoparticles. Finally, we report an electroluminescence power efficiency above 10 −3 %.

“…The most prominent systems are porous silicon, 5 silicon nanocrystals in SiO 2 , 6 p-n diodes, 7,8 Ge + -implanted SiO 2 , 9 and Er-doped silicon-rich SiO 2 sensitized with silicon nanocrystals. 10,11 The latter ones, realized as metal-oxide-semiconductor ͑MOS͒ light emitters, are especially attractive, since they are fully compatible with silicon complementary metal-oxidesemiconductor ͑CMOS͒ technology. Efficient MOS EL devices have been fabricated by erbium-doped silicon-rich SiO 2 with the attractive infrared light emission at 1.54 m for telecommunications.…”

Section: Introductionmentioning

confidence: 99%

Bright green electroluminescence from Tb3+ in silicon metal-oxide-semiconductor devices

Sun

Skorupa

Dekorsy

et al. 2005

Self Cite

112

Bright green electroluminescence with luminance up to 2800 cd/ m 2 is reported from indium-tin-oxide/SiO 2 : Tb/ Si metal-oxide-semiconductor devices. The SiO 2 :Tb 3+ gate oxide was prepared by thermal oxidation followed by Tb + implantation. Electroluminescence and photoluminescence properties were studied with variations of the Tb 3+ ion concentration and the annealing temperature. The optimized device shows a high external quantum efficiency of 16% and a luminous efficiency of 2.1 lm/ W. The excitation processes of the strong green electroluminescence are attributed to the impact excitation of the Tb 3+ luminescent centers by hot electrons and the subsequent crossrelaxation from 5 D 3 to 5 D 4 energy levels. Light-emitting devices with micrometer size fabricated by the standard metal-oxide-semiconductor technology are demonstrated.