Growth of complex SiGe/Ge superlattices by reduced pressure chemical vapour deposition at low temperature

John E. Halpin; Stephen D. Rhead; Ana M. Sanchez; Maksym Myronov; David R. Leadley

doi:10.1088/0268-1242/30/11/114009

Growth of complex SiGe/Ge superlattices by reduced pressure chemical vapour deposition at low temperature

John E. Halpin
, Stephen D. Rhead
, Ana M. Sanchez
, Maksym Myronov
, David R. Leadley

SAMS UHI

Résultats de recherche: Article › Revue par des pairs

6 Citations (Scopus)

Résumé

In this work the growth of complex n-type, high Ge content superlattice structures by reduced pressure chemical vapor deposition is presented. The structures feature 50 repeats of a 14 layer period, which includes a main quantum well that is between 13 and 21 nm wide. The total epitaxy thickness is approximately 8 μm. Diffusion and segregation in the structures was minimized by using a low growth temperature. Materials characterization shows the structures to be of good crystalline quality, with the thickness of all layers close to the design, abrupt interfaces, and uniformity throughout the structures. High angle annular dark field scanning transmission electron microscopy is shown to be an ideal technique for measuring layer thickness and interface quality in these structures.

langue originale	English
Numéro d'article	114009
journal	Semiconductor Science and Technology
Volume	30
Numéro de publication	11
Les DOIs	https://doi.org/10.1088/0268-1242/30/11/114009
état	Published - 15 oct. 2015

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10.1088/0268-1242/30/11/114009License: CC BY-NC-ND

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title = "Growth of complex SiGe/Ge superlattices by reduced pressure chemical vapour deposition at low temperature",

abstract = "In this work the growth of complex n-type, high Ge content superlattice structures by reduced pressure chemical vapor deposition is presented. The structures feature 50 repeats of a 14 layer period, which includes a main quantum well that is between 13 and 21 nm wide. The total epitaxy thickness is approximately 8 μm. Diffusion and segregation in the structures was minimized by using a low growth temperature. Materials characterization shows the structures to be of good crystalline quality, with the thickness of all layers close to the design, abrupt interfaces, and uniformity throughout the structures. High angle annular dark field scanning transmission electron microscopy is shown to be an ideal technique for measuring layer thickness and interface quality in these structures.",

keywords = "epitaxy, multiple quantum well, quantum cascade laser, RP-CVD, SiGe, silicon germanium, superlattice",

author = "Halpin, \{John E.\} and Rhead, \{Stephen D.\} and Sanchez, \{Ana M.\} and Maksym Myronov and Leadley, \{David R.\}",

note = "Publisher Copyright: {\textcopyright} 2015 IOP Publishing Ltd The author was not affiliated to SAMS at the time of publication",

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T1 - Growth of complex SiGe/Ge superlattices by reduced pressure chemical vapour deposition at low temperature

AU - Halpin, John E.

AU - Rhead, Stephen D.

AU - Sanchez, Ana M.

AU - Myronov, Maksym

AU - Leadley, David R.

PY - 2015/10/15

Y1 - 2015/10/15

N2 - In this work the growth of complex n-type, high Ge content superlattice structures by reduced pressure chemical vapor deposition is presented. The structures feature 50 repeats of a 14 layer period, which includes a main quantum well that is between 13 and 21 nm wide. The total epitaxy thickness is approximately 8 μm. Diffusion and segregation in the structures was minimized by using a low growth temperature. Materials characterization shows the structures to be of good crystalline quality, with the thickness of all layers close to the design, abrupt interfaces, and uniformity throughout the structures. High angle annular dark field scanning transmission electron microscopy is shown to be an ideal technique for measuring layer thickness and interface quality in these structures.

AB - In this work the growth of complex n-type, high Ge content superlattice structures by reduced pressure chemical vapor deposition is presented. The structures feature 50 repeats of a 14 layer period, which includes a main quantum well that is between 13 and 21 nm wide. The total epitaxy thickness is approximately 8 μm. Diffusion and segregation in the structures was minimized by using a low growth temperature. Materials characterization shows the structures to be of good crystalline quality, with the thickness of all layers close to the design, abrupt interfaces, and uniformity throughout the structures. High angle annular dark field scanning transmission electron microscopy is shown to be an ideal technique for measuring layer thickness and interface quality in these structures.

KW - epitaxy

KW - multiple quantum well

KW - quantum cascade laser

KW - RP-CVD

KW - SiGe

KW - silicon germanium

KW - superlattice

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UR - https://www.scopus.com/pages/publications/84945533771#tab=citedBy

U2 - 10.1088/0268-1242/30/11/114009

DO - 10.1088/0268-1242/30/11/114009

M3 - Article

AN - SCOPUS:84945533771

SN - 0268-1242

VL - 30

JO - Semiconductor Science and Technology

JF - Semiconductor Science and Technology

IS - 11

M1 - 114009

ER -

Growth of complex SiGe/Ge superlattices by reduced pressure chemical vapour deposition at low temperature

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