Structural and magnetic study of zinc-doped magnetite nanoparticles and ferrofluids for hyperthermia applications

P. MENDOZA ZÉLIS; G. A. PASQUEVICH; S. STEWART; M. B. FERNÁNDEZ VAN RAAP; J. APHESTEGUY; I. J. BRUVERA; C. LABORDE; B. PIANCIOLA; S. JACOBO; F. H. SÁNCHEZ

JOURNAL OF PHYSICS - D (APPLIED PHYSICS)

IOP PUBLISHING LTD

Lugar: Londres; Año: 2013 vol. 46 p. 125006 - 125018

0022-3727

Cubic-like shaped Znx Fe3-x O4 particles with crystallite mean sizes D between 15 and 117 nm were obtained by co-precipitation. Particle size effects and preferential occupation of spinel tetrahedral site by Zn2+ ions led to noticeable changes of physical properties. D 30>nm particles displayed nearly bulk properties, which were dominated by Zn concentration. For D<30 nm, dominant magnetic relaxation effects were observed by Mössbauer spectroscopy, with the mean blocking size DB ∼ 13 to 15 nm. Saturation magnetization increased with x up to x ∼ 0.1-0.3 and decreased for larger x. Power absorbed by water and chitosan-based ferrofluids from a 260 kHz radio frequency field was measured as a function of x, field amplitude H0 and ferrofluid concentration. For H0 = 41 kA m−1 the maximum specific absorption rate was 367 W g−1 for D = 16 nm and x = 0.1. Absorption results are interpreted within the framework of the linear response theory for H0 < 41 kA m−1 . A departure towards a saturation regime was observed for higher fields. Simulations based on a two-level description of nanoparticle magnetic moment relaxation qualitatively agree with these observations. The frequency factor of the susceptibility dissipative component, derived from experimental results, showed a sharp maximum at D ∼ 16 nm. This behaviour was satisfactorily described by simulations based on moment relaxation processes, which furthermore indicated a crossover from Néel to Brown mechanisms at D ∼ 18 nm. Hints for further improvement of magnetite particles as nanocalefactors for magnetic hyperthermia are discussed.