Control of tensile strain in germanium waveguides through silicon nitride layers

A. Ghrib; M. De Kersauson; M. El Kurdi; R. Jakomin; G. Beaudoin; S. Sauvage; G. Fishman; G. Ndong; M. Chaigneau; R. Ossikovski; I. Sagnes; P. Boucaud

doi:10.1063/1.4718525

Control of tensile strain in germanium waveguides through silicon nitride layers

A. Ghrib
, M. De Kersauson
, M. El Kurdi
, R. Jakomin
, G. Beaudoin
, S. Sauvage
, G. Fishman
, G. Ndong
, M. Chaigneau
, R. Ossikovski
, I. Sagnes
, P. Boucaud

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

Abstract

Germanium ridge waveguides can be tensilely strained using silicon nitride thin films as stressors. We show that the strain transfer in germanium depends on the width of the waveguides. Carrier population in the zone center Γ valley can also be significantly increased when the ridges are oriented along the 100 direction. We demonstrate an uniaxial strain transfer up to 1% observed on the room temperature direct band gap photoluminescence of germanium. The results are supported by 30 band k · p modeling of the electronic structure and the finite element modeling of the strain field.

Original language	English
Article number	201104
Journal	Applied Physics Letters
Volume	100
Issue number	20
DOIs	https://doi.org/10.1063/1.4718525
Publication status	Published - 14 May 2012

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10.1063/1.4718525

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@article{24126b05446843a2911667e5ac82891f,

title = "Control of tensile strain in germanium waveguides through silicon nitride layers",

abstract = "Germanium ridge waveguides can be tensilely strained using silicon nitride thin films as stressors. We show that the strain transfer in germanium depends on the width of the waveguides. Carrier population in the zone center Γ valley can also be significantly increased when the ridges are oriented along the 100 direction. We demonstrate an uniaxial strain transfer up to 1\% observed on the room temperature direct band gap photoluminescence of germanium. The results are supported by 30 band k · p modeling of the electronic structure and the finite element modeling of the strain field.",

author = "A. Ghrib and \{De Kersauson\}, M. and \{El Kurdi\}, M. and R. Jakomin and G. Beaudoin and S. Sauvage and G. Fishman and G. Ndong and M. Chaigneau and R. Ossikovski and I. Sagnes and P. Boucaud",

year = "2012",

month = may,

day = "14",

doi = "10.1063/1.4718525",

language = "English",

volume = "100",

journal = "Applied Physics Letters",

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TY - JOUR

T1 - Control of tensile strain in germanium waveguides through silicon nitride layers

AU - Ghrib, A.

AU - De Kersauson, M.

AU - El Kurdi, M.

AU - Jakomin, R.

AU - Beaudoin, G.

AU - Sauvage, S.

AU - Fishman, G.

AU - Ndong, G.

AU - Chaigneau, M.

AU - Ossikovski, R.

AU - Sagnes, I.

AU - Boucaud, P.

PY - 2012/5/14

Y1 - 2012/5/14

N2 - Germanium ridge waveguides can be tensilely strained using silicon nitride thin films as stressors. We show that the strain transfer in germanium depends on the width of the waveguides. Carrier population in the zone center Γ valley can also be significantly increased when the ridges are oriented along the 100 direction. We demonstrate an uniaxial strain transfer up to 1% observed on the room temperature direct band gap photoluminescence of germanium. The results are supported by 30 band k · p modeling of the electronic structure and the finite element modeling of the strain field.

AB - Germanium ridge waveguides can be tensilely strained using silicon nitride thin films as stressors. We show that the strain transfer in germanium depends on the width of the waveguides. Carrier population in the zone center Γ valley can also be significantly increased when the ridges are oriented along the 100 direction. We demonstrate an uniaxial strain transfer up to 1% observed on the room temperature direct band gap photoluminescence of germanium. The results are supported by 30 band k · p modeling of the electronic structure and the finite element modeling of the strain field.

U2 - 10.1063/1.4718525

DO - 10.1063/1.4718525

M3 - Article

AN - SCOPUS:84861809853

SN - 0003-6951

VL - 100

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 20

M1 - 201104

ER -

Control of tensile strain in germanium waveguides through silicon nitride layers

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