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We report a broadband 1H NMR study of the spin dynamics of coated maghemite and gold-maghemite hybrid nanostructures with two different geometries, namely dimers and core-shells. All the samples have a superparamagnetic behavior, displaying a blocking temperature (TB ∼ 80 K (maghemite), ∼105 K (dimer), ∼150 K (core-shell)), and the magnetization reversal time follows the Vogel-Fulcher law. We observed three different anomalies in 1H NMR T1 -1 versus T that decrease in amplitude when increasing the applied magnetic field. We suggest that the anomalies are related to three distinct system dynamics: molecular rotations of the organic groups (240 < T < 270 K), superparamagnetic spin blockage (100 < T < 150 K), and surface-core spin dynamics (T < 25 K). By fitting the T1 -1 data with a heuristic model, we achieved a good agreement with magnetic relaxation data and literature values for methyl group rotation frequencies.

Spin Dynamics in Hybrid Iron Oxide–Gold Nanostructures

ORLANDO, TOMAS;BORDONALI, LORENZO;MARIANI, MANUEL;GALINETTO, PIETRO;CORTI, MAURIZIO ENRICO;GHIGNA, PAOLO;Lascialfari, A.
2015-01-01

Abstract

We report a broadband 1H NMR study of the spin dynamics of coated maghemite and gold-maghemite hybrid nanostructures with two different geometries, namely dimers and core-shells. All the samples have a superparamagnetic behavior, displaying a blocking temperature (TB ∼ 80 K (maghemite), ∼105 K (dimer), ∼150 K (core-shell)), and the magnetization reversal time follows the Vogel-Fulcher law. We observed three different anomalies in 1H NMR T1 -1 versus T that decrease in amplitude when increasing the applied magnetic field. We suggest that the anomalies are related to three distinct system dynamics: molecular rotations of the organic groups (240 < T < 270 K), superparamagnetic spin blockage (100 < T < 150 K), and surface-core spin dynamics (T < 25 K). By fitting the T1 -1 data with a heuristic model, we achieved a good agreement with magnetic relaxation data and literature values for methyl group rotation frequencies.
2015
Applied Physics/Condensed Matter/Materials Science encompasses the resources of three related disciplines: Applied Physics, Condensed Matter Physics, and Materials Science. The applied physics resources are concerned with the applications of topics in condensed matter as well as optics, vacuum science, lasers, electronics, cryogenics, magnets and magnetism, acoustical physics and mechanics. The condensed matter physics resources are concerned with the study of the structure and the thermal, mechanical, electrical, magnetic and optical properties of condensed matter. They include superconductivity, surfaces, interfaces, thin films, dielectrics, ferroelectrics and semiconductors. The materials science resources are concerned with the physics and chemistry of materials and include ceramics, composites, alloys, metals and metallurgy, nanotechnology, nuclear materials, adhesion and adhesives. Resources dealing with polymeric materials are listed in the Organic Chemistry/Polymer Science category.
JOURNAL OF PHYSICAL CHEMISTRY. C
WOS:000348094000042
2-s2.0-84921295209
Esperti anonimi
Inglese
Internazionale
STAMPA
119
2
1224
1233
10
NMR, Spin Dynamics, Nanoparticles
16
info:eu-repo/semantics/article
262
Orlando, Tomas; Capozzi, A.; Umut, E.; Bordonali, Lorenzo; Mariani, Manuel; Galinetto, Pietro; Pineider, F.; Innocenti, C.; Masala, P.; Tabak, F.; Sca...espandi
1 Contributo su Rivista::1.1 Articolo in rivista
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11571/1105775
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