Size-independent low-frequency Raman scattering in Ge-nanocrystal-embedded SiO2 films

L. Z. Liu; X. L. Wu; F. Gao; Y. M. Yang; T. H. Li; Paul K. Chu

Size-independent low-frequency Raman scattering in Ge-nanocrystal-embedded SiO₂ films

L. Z. Liu, X. L. Wu, F. Gao, Y. M. Yang, T. H. Li, Paul K. Chu

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

Abstract

The peak position and linewidth of the low-frequency Raman mode observed from amorphous silica films embedded with Ge nanocrystals doped with Si show a size-independent behavior. Spectral analysis reveals the formation of a thin amorphous GeSi layer on the surface of the Ge nanocrystal. Theoretical calculation based on a modified three-region model discloses that the acoustic impedance of the interfacial GeSiO layer is responsible for the size-independent behavior. During high-temperature annealing, Ge atoms are segregated from the interface into the core, and the GeSiO interface layer is converted to SiO ₂, leading to disappearance of the size-independent vibration mode. © 2010 Optical Society of America.

Original language	English
Pages (from-to)	1022-1024
Journal	Optics Letters
Volume	35
Issue number	7
Publication status	Published - 1 Apr 2010

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@article{845a8088323041388bc9181bb653a65e,

title = "Size-independent low-frequency Raman scattering in Ge-nanocrystal-embedded SiO2 films",

abstract = "The peak position and linewidth of the low-frequency Raman mode observed from amorphous silica films embedded with Ge nanocrystals doped with Si show a size-independent behavior. Spectral analysis reveals the formation of a thin amorphous GeSi layer on the surface of the Ge nanocrystal. Theoretical calculation based on a modified three-region model discloses that the acoustic impedance of the interfacial GeSiO layer is responsible for the size-independent behavior. During high-temperature annealing, Ge atoms are segregated from the interface into the core, and the GeSiO interface layer is converted to SiO 2, leading to disappearance of the size-independent vibration mode. {\textcopyright} 2010 Optical Society of America.",

author = "Liu, {L. Z.} and Wu, {X. L.} and F. Gao and Yang, {Y. M.} and Li, {T. H.} and Chu, {Paul K.}",

year = "2010",

month = apr,

day = "1",

language = "English",

volume = "35",

pages = "1022--1024",

journal = "Optics Letters",

issn = "0146-9592",

publisher = "Optica Publishing Group",

number = "7",

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TY - JOUR

T1 - Size-independent low-frequency Raman scattering in Ge-nanocrystal-embedded SiO2 films

AU - Liu, L. Z.

AU - Wu, X. L.

AU - Gao, F.

AU - Yang, Y. M.

AU - Li, T. H.

AU - Chu, Paul K.

PY - 2010/4/1

Y1 - 2010/4/1

N2 - The peak position and linewidth of the low-frequency Raman mode observed from amorphous silica films embedded with Ge nanocrystals doped with Si show a size-independent behavior. Spectral analysis reveals the formation of a thin amorphous GeSi layer on the surface of the Ge nanocrystal. Theoretical calculation based on a modified three-region model discloses that the acoustic impedance of the interfacial GeSiO layer is responsible for the size-independent behavior. During high-temperature annealing, Ge atoms are segregated from the interface into the core, and the GeSiO interface layer is converted to SiO 2, leading to disappearance of the size-independent vibration mode. © 2010 Optical Society of America.

AB - The peak position and linewidth of the low-frequency Raman mode observed from amorphous silica films embedded with Ge nanocrystals doped with Si show a size-independent behavior. Spectral analysis reveals the formation of a thin amorphous GeSi layer on the surface of the Ge nanocrystal. Theoretical calculation based on a modified three-region model discloses that the acoustic impedance of the interfacial GeSiO layer is responsible for the size-independent behavior. During high-temperature annealing, Ge atoms are segregated from the interface into the core, and the GeSiO interface layer is converted to SiO 2, leading to disappearance of the size-independent vibration mode. © 2010 Optical Society of America.

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UR - https://www.scopus.com/record/pubmetrics.uri?eid=2-s2.0-77954895529&origin=recordpage

M3 - RGC 21 - Publication in refereed journal

SN - 0146-9592

VL - 35

SP - 1022

EP - 1024

JO - Optics Letters

JF - Optics Letters

IS - 7

ER -