Solid phase epitaxy versus random nucleation and growth in sub- 20 nm wide fin field-effect transistors

R. Duffy; M. J.H. Van Dal; B. J. Pawlak; M. Kaiser; R. G.R. Weemaes; B. Degroote; E. Kunnen; E. Altamirano

doi:10.1063/1.2749186

Solid phase epitaxy versus random nucleation and growth in sub- 20 nm wide fin field-effect transistors

R. Duffy
, M. J.H. Van Dal
, B. J. Pawlak
, M. Kaiser
, R. G.R. Weemaes
, B. Degroote
, E. Kunnen
, E. Altamirano

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

Abstract

The authors investigate the implications of amorphizing ion implants on the crystalline integrity of sub- 20 nm wide fin field-effect transistors (FinFETs). Recrystallization of thin body silicon is not as straightforward as that of bulk silicon because the regrowth direction may be parallel to the silicon surface rather than terminating at it. In sub- 20 nm wide FinFETs surface proximity suppresses crystal regrowth and promotes the formation of twin boundary defects in the implanted regions. In the case of a 50 nm amorphization depth, random nucleation and growth leads to polycrystalline silicon formation in the top ∼25 nm of the fin, despite being only ∼25 nm from the crystalline silicon seed.

Original language	English
Article number	241912
Journal	Applied Physics Letters
Volume	90
Issue number	24
DOIs	https://doi.org/10.1063/1.2749186
Publication status	Published - 2007
Externally published	Yes

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10.1063/1.2749186

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title = "Solid phase epitaxy versus random nucleation and growth in sub- 20 nm wide fin field-effect transistors",

abstract = "The authors investigate the implications of amorphizing ion implants on the crystalline integrity of sub- 20 nm wide fin field-effect transistors (FinFETs). Recrystallization of thin body silicon is not as straightforward as that of bulk silicon because the regrowth direction may be parallel to the silicon surface rather than terminating at it. In sub- 20 nm wide FinFETs surface proximity suppresses crystal regrowth and promotes the formation of twin boundary defects in the implanted regions. In the case of a 50 nm amorphization depth, random nucleation and growth leads to polycrystalline silicon formation in the top ∼25 nm of the fin, despite being only ∼25 nm from the crystalline silicon seed.",

author = "R. Duffy and \{Van Dal\}, \{M. J.H.\} and Pawlak, \{B. J.\} and M. Kaiser and Weemaes, \{R. G.R.\} and B. Degroote and E. Kunnen and E. Altamirano",

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doi = "10.1063/1.2749186",

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volume = "90",

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T1 - Solid phase epitaxy versus random nucleation and growth in sub- 20 nm wide fin field-effect transistors

AU - Duffy, R.

AU - Van Dal, M. J.H.

AU - Pawlak, B. J.

AU - Kaiser, M.

AU - Weemaes, R. G.R.

AU - Degroote, B.

AU - Kunnen, E.

AU - Altamirano, E.

PY - 2007

Y1 - 2007

N2 - The authors investigate the implications of amorphizing ion implants on the crystalline integrity of sub- 20 nm wide fin field-effect transistors (FinFETs). Recrystallization of thin body silicon is not as straightforward as that of bulk silicon because the regrowth direction may be parallel to the silicon surface rather than terminating at it. In sub- 20 nm wide FinFETs surface proximity suppresses crystal regrowth and promotes the formation of twin boundary defects in the implanted regions. In the case of a 50 nm amorphization depth, random nucleation and growth leads to polycrystalline silicon formation in the top ∼25 nm of the fin, despite being only ∼25 nm from the crystalline silicon seed.

AB - The authors investigate the implications of amorphizing ion implants on the crystalline integrity of sub- 20 nm wide fin field-effect transistors (FinFETs). Recrystallization of thin body silicon is not as straightforward as that of bulk silicon because the regrowth direction may be parallel to the silicon surface rather than terminating at it. In sub- 20 nm wide FinFETs surface proximity suppresses crystal regrowth and promotes the formation of twin boundary defects in the implanted regions. In the case of a 50 nm amorphization depth, random nucleation and growth leads to polycrystalline silicon formation in the top ∼25 nm of the fin, despite being only ∼25 nm from the crystalline silicon seed.

UR - https://www.scopus.com/pages/publications/34250671643

U2 - 10.1063/1.2749186

DO - 10.1063/1.2749186

M3 - Article

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SN - 0003-6951

VL - 90

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 24

M1 - 241912

ER -

Solid phase epitaxy versus random nucleation and growth in sub- 20 nm wide fin field-effect transistors

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