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Homogenous silver-doped nanocomposite glass

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Homogenous silver-doped nanocomposite glass. / Wackerow, Stefan; Seifert, Gerhard; Abdolvand, Amin.

In: Optical Materials Express, Vol. 1, No. 7, 01.11.2011, p. 1224-1231.

Research output: Contribution to journalArticle

Harvard

Wackerow, S, Seifert, G & Abdolvand, A 2011, 'Homogenous silver-doped nanocomposite glass' Optical Materials Express, vol 1, no. 7, pp. 1224-1231.

APA

Wackerow, S., Seifert, G., & Abdolvand, A. (2011). Homogenous silver-doped nanocomposite glass. Optical Materials Express, 1(7), 1224-1231

Vancouver

Wackerow S, Seifert G, Abdolvand A. Homogenous silver-doped nanocomposite glass. Optical Materials Express. 2011 Nov 1;1(7):1224-1231.

Author

Wackerow, Stefan; Seifert, Gerhard; Abdolvand, Amin / Homogenous silver-doped nanocomposite glass.

In: Optical Materials Express, Vol. 1, No. 7, 01.11.2011, p. 1224-1231.

Research output: Contribution to journalArticle

Bibtex - Download

@article{48b1bb75a6f045bcaf555f896d84e9cc,
title = "Homogenous silver-doped nanocomposite glass",
author = "Stefan Wackerow and Gerhard Seifert and Amin Abdolvand",
year = "2011",
volume = "1",
number = "7",
pages = "1224--1231",
journal = "Optical Materials Express",
issn = "2159-3930",

}

RIS (suitable for import to EndNote) - Download

TY - JOUR

T1 - Homogenous silver-doped nanocomposite glass

A1 - Wackerow,Stefan

A1 - Seifert,Gerhard

A1 - Abdolvand,Amin

AU - Wackerow,Stefan

AU - Seifert,Gerhard

AU - Abdolvand,Amin

PY - 2011/11/1

Y1 - 2011/11/1

N2 - <p>Silver nanoparticles are generated in glass by a dry process. First silver ions are driven into the glass by electric field-assisted ion exchange. Subsequent annealing in air led to the formation of silver nanoparticles beneath the surface of the glass. A thin slice of the cross section of the sample was prepared. This visualization of the depth profile facilitated optical analysis of the embedded layer containing silver nanoparticles to be preformed. We observed that there were narrower plasmon bands close to the sample surface and wider plasmon bands in lower layers. It is attributed to the formation of larger nanoparticles with lower number density close to the surface and slightly smaller nanoparticles with higher number density in the depth of the sample. (C) 2011 Optical Society of America</p>

AB - <p>Silver nanoparticles are generated in glass by a dry process. First silver ions are driven into the glass by electric field-assisted ion exchange. Subsequent annealing in air led to the formation of silver nanoparticles beneath the surface of the glass. A thin slice of the cross section of the sample was prepared. This visualization of the depth profile facilitated optical analysis of the embedded layer containing silver nanoparticles to be preformed. We observed that there were narrower plasmon bands close to the sample surface and wider plasmon bands in lower layers. It is attributed to the formation of larger nanoparticles with lower number density close to the surface and slightly smaller nanoparticles with higher number density in the depth of the sample. (C) 2011 Optical Society of America</p>

KW - SIZE DEPTH PROFILE

KW - SODA-LIME GLASS

KW - ION-EXCHANGE

KW - WAVE-GUIDES

KW - SILICATE GLASS

KW - ELECTRIC-FIELD

KW - OPTICAL-ABSORPTION

KW - AG NANOPARTICLES

KW - DIFFUSION

KW - SODIUM

M1 - Article

JO - Optical Materials Express

JF - Optical Materials Express

SN - 2159-3930

IS - 7

VL - 1

SP - 1224

EP - 1231

ER -

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