Selective area growth of InP and defect elimination on Si (001) substrates

Gang Wang; Maarten Leys; Roger Loo; Olivier Richard; Hugo Bender; Guy Brammertz; Niamh Waldron; Wei E. Wang; Johan Dekoster; Matty Caymax; Marc Seefeldt; Marc Heyns

doi:10.1149/1.3571248

Selective area growth of InP and defect elimination on Si (001) substrates

Gang Wang
, Maarten Leys
, Roger Loo
, Olivier Richard
, Hugo Bender
, Guy Brammertz
, Niamh Waldron
, Wei E. Wang
, Johan Dekoster
, Matty Caymax
, Marc Seefeldt
, Marc Heyns

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

Abstract

We report the selective area growth of InP layers in submicron trenches on Si (001) substrates by using a thin Ge buffer layer. The antiphase domain boundaries in InP layers are suppressed by engineering the local Ge surface profile. The mechanism of atomic step formation and the corresponding method for step density control are presented. We discuss the impact of the surface profile of the Ge buffer layer on the formation of antiphase domain boundaries as well as on InP nucleation. A minimum step density of 0.25 nm^-1 is required to avoid antiphase domain boundaries while a higher step density substantially reduces the stacking faults and twins in the InP nucleation layer. By employing the threading dislocation necking effect and the properly controlled Ge surface profile, high-quality InP layers have been obtained in submicron trenches.

Original language	English
Pages (from-to)	H645-H650
Journal	Journal of the Electrochemical Society
Volume	158
Issue number	6
DOIs	https://doi.org/10.1149/1.3571248
Publication status	Published - 2011
Externally published	Yes

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10.1149/1.3571248

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title = "Selective area growth of InP and defect elimination on Si (001) substrates",

abstract = "We report the selective area growth of InP layers in submicron trenches on Si (001) substrates by using a thin Ge buffer layer. The antiphase domain boundaries in InP layers are suppressed by engineering the local Ge surface profile. The mechanism of atomic step formation and the corresponding method for step density control are presented. We discuss the impact of the surface profile of the Ge buffer layer on the formation of antiphase domain boundaries as well as on InP nucleation. A minimum step density of 0.25 nm-1 is required to avoid antiphase domain boundaries while a higher step density substantially reduces the stacking faults and twins in the InP nucleation layer. By employing the threading dislocation necking effect and the properly controlled Ge surface profile, high-quality InP layers have been obtained in submicron trenches.",

author = "Gang Wang and Maarten Leys and Roger Loo and Olivier Richard and Hugo Bender and Guy Brammertz and Niamh Waldron and Wang, \{Wei E.\} and Johan Dekoster and Matty Caymax and Marc Seefeldt and Marc Heyns",

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doi = "10.1149/1.3571248",

language = "English",

volume = "158",

pages = "H645--H650",

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TY - JOUR

T1 - Selective area growth of InP and defect elimination on Si (001) substrates

AU - Wang, Gang

AU - Leys, Maarten

AU - Loo, Roger

AU - Richard, Olivier

AU - Bender, Hugo

AU - Brammertz, Guy

AU - Waldron, Niamh

AU - Wang, Wei E.

AU - Dekoster, Johan

AU - Caymax, Matty

AU - Seefeldt, Marc

AU - Heyns, Marc

PY - 2011

Y1 - 2011

N2 - We report the selective area growth of InP layers in submicron trenches on Si (001) substrates by using a thin Ge buffer layer. The antiphase domain boundaries in InP layers are suppressed by engineering the local Ge surface profile. The mechanism of atomic step formation and the corresponding method for step density control are presented. We discuss the impact of the surface profile of the Ge buffer layer on the formation of antiphase domain boundaries as well as on InP nucleation. A minimum step density of 0.25 nm-1 is required to avoid antiphase domain boundaries while a higher step density substantially reduces the stacking faults and twins in the InP nucleation layer. By employing the threading dislocation necking effect and the properly controlled Ge surface profile, high-quality InP layers have been obtained in submicron trenches.

AB - We report the selective area growth of InP layers in submicron trenches on Si (001) substrates by using a thin Ge buffer layer. The antiphase domain boundaries in InP layers are suppressed by engineering the local Ge surface profile. The mechanism of atomic step formation and the corresponding method for step density control are presented. We discuss the impact of the surface profile of the Ge buffer layer on the formation of antiphase domain boundaries as well as on InP nucleation. A minimum step density of 0.25 nm-1 is required to avoid antiphase domain boundaries while a higher step density substantially reduces the stacking faults and twins in the InP nucleation layer. By employing the threading dislocation necking effect and the properly controlled Ge surface profile, high-quality InP layers have been obtained in submicron trenches.

UR - https://www.scopus.com/pages/publications/79955548861

U2 - 10.1149/1.3571248

DO - 10.1149/1.3571248

M3 - Article

AN - SCOPUS:79955548861

SN - 0013-4651

VL - 158

SP - H645-H650

JO - Journal of the Electrochemical Society

JF - Journal of the Electrochemical Society

IS - 6

ER -

Selective area growth of InP and defect elimination on Si (001) substrates

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