Spontaneous Formation of Core@shell Co@Cr Nanoparticles by Gas Phase Synthesis

This work presents the gas phase synthesis of CoCr nanoparticles using a magnetron-based gas aggregation source. The effect of the particle size and Co/Cr ratio on the properties of the nanoparticles is investigated. In particular, we report the synthesis of nanoparticles from two alloy targets, Co9...

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Bibliographic Details
Published in:Applied nano 2020-12, Vol.1 (1), p.87-101
Main Authors: Soler-Morala, Jimena, Jefremovas, Elizabeth M., Martínez, Lidia, Mayoral, Álvaro, Sánchez, Elena H., De Toro, Jose A., Navarro, Elena, Huttel, Yves
Format: Article
Language:English
Subjects:
Energy
Magnetic anisotropy
Magnetic fields
Magnetism
Morphology
Nanoalloys
Nanoparticles
Sensors
Shells (structural forms)
Spectrum analysis
Synthesis
Thermal stability
Transmission electron microscopy
Vapor phases
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Summary:This work presents the gas phase synthesis of CoCr nanoparticles using a magnetron-based gas aggregation source. The effect of the particle size and Co/Cr ratio on the properties of the nanoparticles is investigated. In particular, we report the synthesis of nanoparticles from two alloy targets, Co90Cr10 and Co80Cr20. In the first case, we observe a size threshold for the spontaneous formation of a segregated core@shell structure, related to the surface to volume ratio. When this ratio is above one, a shell cannot be properly formed, whereas when this ratio decreases below unity the proportion of Cr atoms is high enough to allow the formation of a shell. In the latter case, the segregation of the Cr atoms towards the surface gives rise to the formation of a shell surrounding the Co core. When the proportion of Cr is increased in the target (Co80Cr20), a thicker shell is spontaneously formed for a similar nanoparticle size. The magnetic response was evaluated, and the influence of the structure and composition of the nanoparticles is discussed. An enhancement of the global magnetic anisotropy caused by exchange bias and dipolar interactions, which enables the thermal stability of the studied small particles up to relatively large temperatures, is reported.
ISSN:2673-3501
2673-3501
DOI:10.3390/applnano1010007