Role of silicon interstitials in boron cluster dissolution

Maria Aboy; Lourdes Pelaz; Luis A. Marqús; Pedro López; Juan Barbolla; R. Duffy; V. C. Venezia; Peter B. Griffin

doi:10.1063/1.1852728

Role of silicon interstitials in boron cluster dissolution

Maria Aboy
, Lourdes Pelaz
, Luis A. Marqús
, Pedro López
, Juan Barbolla
, R. Duffy
, V. C. Venezia
, Peter B. Griffin

Research output: Contribution to journal › Article › peer-review

Abstract

We present kinetic nonlattice Monte Carlo atomistic simulations to investigate the role of Si interstitials in B cluster dissolution. We show that the presence of Si interstitials from an oxidizing anneal stabilize B clusters and slow down B cluster dissolution, compared to anneal in inert ambient. We have also analyzed the influence of injected Si interstitials from end of range defects, due to preamorphizing implants, on B deactivation and reactivation processes. We have observed that the B cluster evolution can be clearly correlated to the evolution of Si interstitial defects at the end of range. The minimum level of activation occurs when the Si interstitial supersaturation is low because the end of range defects have dissolved or reach very stable configurations, such as dislocation loops.

Original language	English
Article number	031908
Pages (from-to)	1-3
Number of pages	3
Journal	Applied Physics Letters
Volume	86
Issue number	3
DOIs	https://doi.org/10.1063/1.1852728
Publication status	Published - 17 Jan 2005
Externally published	Yes

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title = "Role of silicon interstitials in boron cluster dissolution",

abstract = "We present kinetic nonlattice Monte Carlo atomistic simulations to investigate the role of Si interstitials in B cluster dissolution. We show that the presence of Si interstitials from an oxidizing anneal stabilize B clusters and slow down B cluster dissolution, compared to anneal in inert ambient. We have also analyzed the influence of injected Si interstitials from end of range defects, due to preamorphizing implants, on B deactivation and reactivation processes. We have observed that the B cluster evolution can be clearly correlated to the evolution of Si interstitial defects at the end of range. The minimum level of activation occurs when the Si interstitial supersaturation is low because the end of range defects have dissolved or reach very stable configurations, such as dislocation loops.",

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T1 - Role of silicon interstitials in boron cluster dissolution

AU - Aboy, Maria

AU - Pelaz, Lourdes

AU - Marqús, Luis A.

AU - López, Pedro

AU - Barbolla, Juan

AU - Duffy, R.

AU - Venezia, V. C.

AU - Griffin, Peter B.

PY - 2005/1/17

Y1 - 2005/1/17

N2 - We present kinetic nonlattice Monte Carlo atomistic simulations to investigate the role of Si interstitials in B cluster dissolution. We show that the presence of Si interstitials from an oxidizing anneal stabilize B clusters and slow down B cluster dissolution, compared to anneal in inert ambient. We have also analyzed the influence of injected Si interstitials from end of range defects, due to preamorphizing implants, on B deactivation and reactivation processes. We have observed that the B cluster evolution can be clearly correlated to the evolution of Si interstitial defects at the end of range. The minimum level of activation occurs when the Si interstitial supersaturation is low because the end of range defects have dissolved or reach very stable configurations, such as dislocation loops.

AB - We present kinetic nonlattice Monte Carlo atomistic simulations to investigate the role of Si interstitials in B cluster dissolution. We show that the presence of Si interstitials from an oxidizing anneal stabilize B clusters and slow down B cluster dissolution, compared to anneal in inert ambient. We have also analyzed the influence of injected Si interstitials from end of range defects, due to preamorphizing implants, on B deactivation and reactivation processes. We have observed that the B cluster evolution can be clearly correlated to the evolution of Si interstitial defects at the end of range. The minimum level of activation occurs when the Si interstitial supersaturation is low because the end of range defects have dissolved or reach very stable configurations, such as dislocation loops.

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U2 - 10.1063/1.1852728

DO - 10.1063/1.1852728

M3 - Article

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SN - 0003-6951

VL - 86

SP - 1

EP - 3

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 3

M1 - 031908

ER -

Role of silicon interstitials in boron cluster dissolution

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