Spin disorder in maghemite nanoparticles investigated using polarized neutrons and nuclear resonant scattering

M. Herlitschke; S. Disch; I. Sergueev; K. Schlage; E. Wetterskog; L. Bergström; R. P. Hermann

doi:10.1088/1742-6596/711/1/012002

Spin disorder in maghemite nanoparticles investigated using polarized neutrons and nuclear resonant scattering

M. Herlitschke, S. Disch, I. Sergueev, K. Schlage, E. Wetterskog, L. Bergström, R. P. Hermann

Neutron & X-Ray Scattering, & Thermophys

Research output: Contribution to journal › Conference article › peer-review

16 Scopus citations

Abstract

The manuscript reports the investigation of spin disorder in maghemite nanoparticles of different shape by a combination of polarized small-angle neutron scattering (SANSPOL) and nuclear forward scattering (NFS) techniques. Both methods are sensitive to magnetization on the nanoscale. SANSPOL allows for investigation of the particle morphology and spatial magnetization distribution and NFS extends this nanoscale information to the atomic scale, namely the orientation of the hyperfine field experienced by the iron nuclei. The studied nanospheres and nanocubes with diameters of 7.4 nm and 10.6 nm, respectively, exhibit a significant spin disorder. This effect leads to a reduction of the magnetization to 44% and 58% of the theoretical maghemite bulk value, observed consistently by both techniques.

Original language	English
Article number	012002
Journal	Journal of Physics: Conference Series
Volume	711
Issue number	1
DOIs	https://doi.org/10.1088/1742-6596/711/1/012002
State	Published - May 11 2016
Event	10th International Conference on Polarised Neutrons for Condensed Matter Investigations, PNCMI 2014 - Sydney, Australia Duration: Sep 15 2014 → Sep 19 2014

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abstract = "The manuscript reports the investigation of spin disorder in maghemite nanoparticles of different shape by a combination of polarized small-angle neutron scattering (SANSPOL) and nuclear forward scattering (NFS) techniques. Both methods are sensitive to magnetization on the nanoscale. SANSPOL allows for investigation of the particle morphology and spatial magnetization distribution and NFS extends this nanoscale information to the atomic scale, namely the orientation of the hyperfine field experienced by the iron nuclei. The studied nanospheres and nanocubes with diameters of 7.4 nm and 10.6 nm, respectively, exhibit a significant spin disorder. This effect leads to a reduction of the magnetization to 44% and 58% of the theoretical maghemite bulk value, observed consistently by both techniques.",

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T1 - Spin disorder in maghemite nanoparticles investigated using polarized neutrons and nuclear resonant scattering

AU - Herlitschke, M.

AU - Disch, S.

AU - Sergueev, I.

AU - Schlage, K.

AU - Wetterskog, E.

AU - Bergström, L.

AU - Hermann, R. P.

PY - 2016/5/11

Y1 - 2016/5/11

N2 - The manuscript reports the investigation of spin disorder in maghemite nanoparticles of different shape by a combination of polarized small-angle neutron scattering (SANSPOL) and nuclear forward scattering (NFS) techniques. Both methods are sensitive to magnetization on the nanoscale. SANSPOL allows for investigation of the particle morphology and spatial magnetization distribution and NFS extends this nanoscale information to the atomic scale, namely the orientation of the hyperfine field experienced by the iron nuclei. The studied nanospheres and nanocubes with diameters of 7.4 nm and 10.6 nm, respectively, exhibit a significant spin disorder. This effect leads to a reduction of the magnetization to 44% and 58% of the theoretical maghemite bulk value, observed consistently by both techniques.

AB - The manuscript reports the investigation of spin disorder in maghemite nanoparticles of different shape by a combination of polarized small-angle neutron scattering (SANSPOL) and nuclear forward scattering (NFS) techniques. Both methods are sensitive to magnetization on the nanoscale. SANSPOL allows for investigation of the particle morphology and spatial magnetization distribution and NFS extends this nanoscale information to the atomic scale, namely the orientation of the hyperfine field experienced by the iron nuclei. The studied nanospheres and nanocubes with diameters of 7.4 nm and 10.6 nm, respectively, exhibit a significant spin disorder. This effect leads to a reduction of the magnetization to 44% and 58% of the theoretical maghemite bulk value, observed consistently by both techniques.

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DO - 10.1088/1742-6596/711/1/012002

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Spin disorder in maghemite nanoparticles investigated using polarized neutrons and nuclear resonant scattering

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