Incorporation of high concentrations of erbium in crystal silicon

Polman, A.; Custer, J. S.; Snoeks, E.; Hoven, G.N. van den

doi:10.1063/1.108894

Cited by 94 publications

(31 citation statements)

References 14 publications

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“…6,7 Er-doped silicon is an interesting optoelectronic material, due to optical transitions in the internal 4 f shell of Er 3ϩ , 8 and in order to fully exploit the possibilities of this material, detailed knowledge of the incorporation behavior of Er in Si is required. The equilibrium solubility of Er in c-Si is unknown, but by analogy to the transition metals 9 it is estimated to be 10 14 -10 16 cm Ϫ3 .…”

Section: Introductionmentioning

confidence: 99%

Segregation and trapping of erbium at a moving crystal-amorphous Si interface

Polman

Custer

Zagwijn

et al. 1997

Journal of Applied Physics

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Segregation and trapping of Er during solid-phase crystallization of amorphous Si on crystalline Si is studied in a concentration range of 10 16 -5ϫ10 20 Er/cm 3 . Amorphous surface layers are prepared on Si͑100͒ by 250 keV Er ion implantation, recrystallized at 600°C, and then analyzed using high-resolution Rutherford backscattering spectrometry using 2 MeV He ϩ or 100 keV H ϩ . The segregation coefficient k depends strongly on Er concentration. At Er interface areal densities below 6ϫ10 13 Er/cm 2 nearly full segregation to the surface is observed, with kϭ0.01. At higher Er densities, segregation and trapping in the crystal are observed, with kϭ0.20. The results are consistent with a model in which it is assumed that defects in the a-Si near the interface act as traps for the Er.

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Section: Introductionmentioning

confidence: 99%

Segregation and trapping of erbium at a moving crystal-amorphous Si interface

Polman

Custer

Zagwijn

et al. 1997

Journal of Applied Physics

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“…16 At a temperature of 620°C efficient SPE regrowth is occurring and annealing for 3 h ͑treatment B͒ is sufficient for the a-c Si interface to traverse the implanted region. In the absence of O, Polman et al 12 have shown that recrystallization produces a redistribution of Er atoms through the migration of the Er ahead of the a-c interface. This will ultimately lead to the formation of clusters of Er and Si atoms and to the formation of Er silicide precipitates.…”

Section: B Effects Of Different Anneal Treatments On the O Codoped Smentioning

confidence: 99%

“…Recrystallization of the amorphous region will occur once the annealing temperature exceeds the crystallization temperature in Si ͑ϳ550°C͒. 12 Sample O3 only received thermal treatment A and the absence of an EPR signal can be explained in terms of little or no SPE regrowth occurring in this sample. EXAFS measurements on this sample have shown that the six nearest neighbors of Er are all Si and that the local environment is ErSi 2 like.…”

Section: B Effects Of Different Anneal Treatments On the O Codoped Smentioning

confidence: 99%

“…[1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16] The 4f electrons are shielded from the full effects of the host crystal field and this results in the intra-4f shell optical transitions being both sharp and nearly independent of the host material. Furthermore, due to the close proximity of the 4f electrons to the nucleus, these electrons experience a strong spin-orbit interaction.…”

Section: Introductionmentioning

confidence: 99%

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Electron paramagnetic resonance and photoluminescence study of Er-impurity complexes in Si

et al. 1999

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Electron paramagnetic resonance ͑EPR͒ and photoluminescence ͑PL͒ spectroscopy have been used to examine the structure and optical properties of erbium-impurity complexes formed in float-zone Si by multipleenergy implants at 77 K of Er together with either O or F. After implantation a 2-m-thick amorphous layer was formed containing an almost uniform concentration of Er (10 19 /cm 3 )and O (3ϫ10 19 /cm 3 or 10 20 /cm 3 ) or F (10 20 /cm 3 ). Samples were annealed in nitrogen at 450°C for 30 min ͑treatment A͒, treatment Aϩ620°C for 3 h ͑treatment B͒, treatment Bϩ900°C for 30 s ͑treatment C͒ or treatment Bϩ900°C for 30 min ͑treatment D͒. Samples coimplanted to have 3ϫ10 19 O/cm 3 and subject to treatment C show a broad line anisotropic EPR spectrum. These samples have the most intense low-temperature PL spectrum containing several sharp peaks attributed to Er 3ϩ in sites with predominantly cubic T d symmetry. Increasing the O concentration to 10 20 /cm 3 produces sharp line EPR spectra the strongest of which are attributed to two Er 3ϩ centers having monoclinic C 1h and trigonal symmetry. The principal g values and tilt angle for the monoclinic centers are g 1 ϭ0.80, g 2 ϭ5.45, g 3 ϭ12.60, ϭ57.3°, g ʈ ϭ0.69, and g Ќ ϭ3.24 for the trigonal centers. The low-temperature PL spectrum from this sample showed additional sharp lines but the total intensity is reduced when compared to the sample with 3ϫ10 19 O/cm 3 . For the sample containing 10 20 O/cm 3 at least four distinct centers are observed by EPR after treatment B but after treatment D no EPR spectrum is observed. The PL spectra are also observed to change depending on the specific anneal treatment but even after treatment D, Er-related PL is still observed. Samples containing 10 20 F/cm 3 and annealed with either treatment B or C produced an EPR spectrum attributed to Er 3ϩ in a site of monoclinic C 1h symmetry with g 1 ϭ1.36, g 2 ϭ9.65, g 3 ϭ7.91, and ϭ79.1°.Tentative models for the structures of Er-impurity complexes are presented and the relationship between the EPR-active and PL-active centers is discussed. ͓S0163-1829͑99͒04503-8͔

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“…Recently, Polman et al 23 have shown that high concentrations of erbium can be achieved by ion-implantation followed by an annealing stage at 600 0 C. The Er incorporated substitutionally in this way can then be optically activated by a subsequent heat treatment step at 1000oC. We have adopted a different approach towards the same goal of large erbium concentrations.…”

Section: Discussionmentioning

confidence: 96%

Er³⁺-Doped Silicon Prepared by Laser Doping

et al. 1993

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We have carried out an investigation of the laser doping of Si with rare-earth ions. In this technique a silicon surface coated with a thin layer of the rare-earth metal is melted with a pulsed laser, the dopant is mixed in the molten layer, and incorporated in the crystal during regrowth. Er was chosen for the main part of our work as it is the best characterized of the rare-earth ions in Si. Luminescence is observed around 1.541tm and is assigned to optical transitions on Er 3 + ions. This preliminary study shows that this new technique is viable for the production of optically active Er 3 ÷ in Si.

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Incorporation of high concentrations of erbium in crystal silicon

Cited by 94 publications

References 14 publications

Segregation and trapping of erbium at a moving crystal-amorphous Si interface

Segregation and trapping of erbium at a moving crystal-amorphous Si interface

Electron paramagnetic resonance and photoluminescence study of Er-impurity complexes in Si

Er³⁺-Doped Silicon Prepared by Laser Doping

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Incorporation of high concentrations of erbium in crystal silicon

Cited by 94 publications

References 14 publications

Segregation and trapping of erbium at a moving crystal-amorphous Si interface

Segregation and trapping of erbium at a moving crystal-amorphous Si interface

Electron paramagnetic resonance and photoluminescence study of Er-impurity complexes in Si

Er3+-Doped Silicon Prepared by Laser Doping

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Er³⁺-Doped Silicon Prepared by Laser Doping