On the formation of ternary metallic-dielectric multicore-shell nanoparticles by inert-gas condensation method

Maria Benelmekki; Jerome Vernieres; Jeong Hwan Kim; Rosa E. Diaz; Panagiotis Grammatikopoulos; Mukhles Sowwan

doi:10.1016/j.matchemphys.2014.11.066

On the formation of ternary metallic-dielectric multicore-shell nanoparticles by inert-gas condensation method

Maria Benelmekki^*, Jerome Vernieres, Jeong Hwan Kim, Rosa E. Diaz, Panagiotis Grammatikopoulos, Mukhles Sowwan

^*Corresponding author for this work

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

39 Scopus citations

Abstract

Magneto-plasmonic hybrid nanoparticles (HNPs) are promising for a large number for dual magneto-optical bioapplications. Gas-phase techniques offer a good alternative to chemical routes for the generation of tailored HNPs. Here, we present a novel method to synthesize ternary HNPs composed of multiple dumbbell-like FeAg cores encapsulated by an amorphous Si shell. The method involves a simultaneous sputtering of Fe, Ag and Si targets under controlled conditions. We demonstrate that the morphology and the size of the HNPs can be modulated by tuning experimental parameters such as the energy and the cooling rate, or the collision and coalescence processes experienced by the HNPs during their formation. We find that by increasing the residence time of the HNPs in the aggregation zone, we increase both the size of the HNPs, and the thickness of the Si shell. HNPs exhibit ferromagnetic behavior and show an enhanced, red-shifted, light absorption band due to the strong near-field coupling between the Ag cores and the Si shell. A mechanism of formation of these HNPs is suggested, combining the physico-chemical properties of the materials (Fe, Ag, Si) with the experimental conditions.

Original language	English
Pages (from-to)	275-281
Number of pages	7
Journal	Materials Chemistry and Physics
Volume	151
DOIs	https://doi.org/10.1016/j.matchemphys.2014.11.066
State	Published - 1 Feb 2015
Externally published	Yes

Keywords

Biomaterials
Magnetic properties
Optical properties
Sputtering

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10.1016/j.matchemphys.2014.11.066

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title = "On the formation of ternary metallic-dielectric multicore-shell nanoparticles by inert-gas condensation method",

abstract = "Magneto-plasmonic hybrid nanoparticles (HNPs) are promising for a large number for dual magneto-optical bioapplications. Gas-phase techniques offer a good alternative to chemical routes for the generation of tailored HNPs. Here, we present a novel method to synthesize ternary HNPs composed of multiple dumbbell-like FeAg cores encapsulated by an amorphous Si shell. The method involves a simultaneous sputtering of Fe, Ag and Si targets under controlled conditions. We demonstrate that the morphology and the size of the HNPs can be modulated by tuning experimental parameters such as the energy and the cooling rate, or the collision and coalescence processes experienced by the HNPs during their formation. We find that by increasing the residence time of the HNPs in the aggregation zone, we increase both the size of the HNPs, and the thickness of the Si shell. HNPs exhibit ferromagnetic behavior and show an enhanced, red-shifted, light absorption band due to the strong near-field coupling between the Ag cores and the Si shell. A mechanism of formation of these HNPs is suggested, combining the physico-chemical properties of the materials (Fe, Ag, Si) with the experimental conditions.",

keywords = "Biomaterials, Magnetic properties, Optical properties, Sputtering",

author = "Maria Benelmekki and Jerome Vernieres and Kim, {Jeong Hwan} and Diaz, {Rosa E.} and Panagiotis Grammatikopoulos and Mukhles Sowwan",

year = "2015",

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doi = "10.1016/j.matchemphys.2014.11.066",

language = "英语",

volume = "151",

pages = "275--281",

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T1 - On the formation of ternary metallic-dielectric multicore-shell nanoparticles by inert-gas condensation method

AU - Benelmekki, Maria

AU - Vernieres, Jerome

AU - Kim, Jeong Hwan

AU - Diaz, Rosa E.

AU - Grammatikopoulos, Panagiotis

AU - Sowwan, Mukhles

PY - 2015/2/1

Y1 - 2015/2/1

N2 - Magneto-plasmonic hybrid nanoparticles (HNPs) are promising for a large number for dual magneto-optical bioapplications. Gas-phase techniques offer a good alternative to chemical routes for the generation of tailored HNPs. Here, we present a novel method to synthesize ternary HNPs composed of multiple dumbbell-like FeAg cores encapsulated by an amorphous Si shell. The method involves a simultaneous sputtering of Fe, Ag and Si targets under controlled conditions. We demonstrate that the morphology and the size of the HNPs can be modulated by tuning experimental parameters such as the energy and the cooling rate, or the collision and coalescence processes experienced by the HNPs during their formation. We find that by increasing the residence time of the HNPs in the aggregation zone, we increase both the size of the HNPs, and the thickness of the Si shell. HNPs exhibit ferromagnetic behavior and show an enhanced, red-shifted, light absorption band due to the strong near-field coupling between the Ag cores and the Si shell. A mechanism of formation of these HNPs is suggested, combining the physico-chemical properties of the materials (Fe, Ag, Si) with the experimental conditions.

AB - Magneto-plasmonic hybrid nanoparticles (HNPs) are promising for a large number for dual magneto-optical bioapplications. Gas-phase techniques offer a good alternative to chemical routes for the generation of tailored HNPs. Here, we present a novel method to synthesize ternary HNPs composed of multiple dumbbell-like FeAg cores encapsulated by an amorphous Si shell. The method involves a simultaneous sputtering of Fe, Ag and Si targets under controlled conditions. We demonstrate that the morphology and the size of the HNPs can be modulated by tuning experimental parameters such as the energy and the cooling rate, or the collision and coalescence processes experienced by the HNPs during their formation. We find that by increasing the residence time of the HNPs in the aggregation zone, we increase both the size of the HNPs, and the thickness of the Si shell. HNPs exhibit ferromagnetic behavior and show an enhanced, red-shifted, light absorption band due to the strong near-field coupling between the Ag cores and the Si shell. A mechanism of formation of these HNPs is suggested, combining the physico-chemical properties of the materials (Fe, Ag, Si) with the experimental conditions.

KW - Biomaterials

KW - Magnetic properties

KW - Optical properties

KW - Sputtering

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DO - 10.1016/j.matchemphys.2014.11.066

M3 - 文章

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SP - 275

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JO - Materials Chemistry and Physics

JF - Materials Chemistry and Physics

ER -

On the formation of ternary metallic-dielectric multicore-shell nanoparticles by inert-gas condensation method

Abstract

Keywords

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