Effect of implant temperature on transient enhanced diffusion of boron in regrown silicon after amorphization by Si+ or Ge+ implantation

Jones, K. S.; Möller, K.; Chen, J.; Puga-Lambers, M.; Freer, B. S.; Berstein, J.; Rubin, L.

doi:10.1063/1.364391

Cited by 44 publications

(19 citation statements)

References 20 publications

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“…Furthermore, Jones et al 11 reported that low-temperature amorphizing implants led to dislocation loops which did not hamper the flow of interstitials across the amorphous/crystalline interface. As the Si ϩ implant in our work was performed using liquid-nitrogen cooling, this mechanism could also contribute to increased arsenic diffusion in the Si ϩ implanted layers.…”

Section: Discussionmentioning

confidence: 99%

Comparison of arsenic diffusion in Si1−xGex formed by epitaxy and Ge+ implantation

Mitchell

Ashburn

Bonar

et al. 2003

Journal of Applied Physics

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A comparison is made of arsenic diffusion in Si 0.95 Ge 0.05 produced by epitaxy and ion beam synthesis using a 2ϫ10 16 cm Ϫ2 Ge ϩ implant into silicon. The arsenic diffusion depth at 1025°C in the Si 0.95 Ge 0.05 epitaxy sample is enhanced by a factor of 1.26 compared with a similar Si control sample and by a factor of 1.30 in the ion beam synthesized sample. The arsenic diffusion in the Si 0.95 Ge 0.05 epitaxy sample is modeled by increasing the arsenic diffusion coefficient from the Si value of 1.92ϫ10 Ϫ15 to 5.15ϫ10 Ϫ15 cm 2 s Ϫ1 , and in the ion beam synthesized sample by using the same diffusion coefficient of 5.15ϫ10 Ϫ15 cm 2 s Ϫ1 and increasing the ''plus one'' factor in the transient enhanced diffusion model from 0.01 to 1.5. Arsenic diffusion in a silicon sample implanted with 2ϫ10 15 cm Ϫ2 Si ϩ can be modeled using the same plus one factor of 1.5, thereby demonstrating the consistency of the modeling.

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Section: Discussionmentioning

confidence: 99%

Comparison of arsenic diffusion in Si1−xGex formed by epitaxy and Ge+ implantation

Mitchell

Ashburn

Bonar

et al. 2003

Journal of Applied Physics

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“…They are elongated along <110> directions and lie in {311} planes and were therefore identified as {311} defects. These defects are known to be formed at the EOR after recrystallization of amorphous layer created by Si or Ge implantation [18,19]. In the case of Li implantation at liquid nitrogen temperature, they were not observed after annealing at 600 °C for 30 minutes [12].…”

Section: Buried Amorphous Layermentioning

confidence: 99%

Interaction of interstitials with buried amorphous layer in silicon

Oliviero

David

Fichtner

2009

Phys. Status Solidi (c)

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International audienceBuried amorphous layers have been produced in silicon single crystal by lithium implantation at liquid nitrogen temperature and followed by a 400 degrees C annealing. By this process, a wide region, perfectly crystalline and free of any extended defect, is formed ahead of the buried amorphous layer up to the implanted surface. Neon has then been implanted in this front region at high fluence and high temperature (250 degrees C) in order to create bubbles and avoid further amorphization. In the presence of a buried amorphous layer, significant decrease of the extended defect density is observed at the neon end of range region. The results are discussed in terms of interstitial trapping, i.e. the buried amorphous layer acting as an efficient sink for interstitials during recrystallization. (C) 2009 WILEY-VCH Verlag GmbH & Co. KGaA, Weinhei

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“…Of the various choices for pre-amorphization species, Ge þ is the most promising amorphization agent (Jones et al, 1997) primarily because it is known to result in lower sheet resistance than either argon or fluorine (Colombeau et al, 2004). The advantage of Ge over Si is that the former is a heavier atom and therefore, a lower implantation dose is sufficient to create a uniform amorphous layer.…”

Section: Concentration Concentrationmentioning

confidence: 99%