Magneto-optical properties of superparamagnetic spinel ferrite nanoparticles

Anderson, Richard M.

08 1900

No description available.

Ferrite Magnetic properties

Spinel Magnetic properties

Nanoparticles Magnetic properties

Magnetooptics

Magnetic couplings and superparamagnetic properties of spinel ferrite nanoparticles

Vestal, Christy Riann

03 1900

No description available.

Ferromagnetism

Ferrites (Magnetic materials)

Nanoparticles Magnetic properties

Spinel Magnetic properties

Ferrites (Magnetic materials)

Ferromagnetism

Nanoparticles Magnetic properties

Spinel Magnetic properties

Sinteza i karakterizacija nanočestičnih prahova na bazi cink-ferita / Synthesis and characterisation of nanoparticles based on zinc-ferrites

Milanović Marija

02 July 2010

<p>U ovom radu prikazani su rezultati ispitivanja strukturnih i magnetnih osobina čistih cink- ferita, ZnFe₂O₄ i cink-ferita sa dodatkom indijuma Zn_1-xIn_xFe₂O₄ i itrijuma, ZnY_xFe_2-xO₄, gde je 0 &le; x &le; 0,6. Prahovi na bazi cink-ferita su sintetisani koristeći nisko temperaturnu metodu sinteze iz tečne faze &ndash; metodu koprecipitacije. Osnovni cilj ove doktorske disertacije je bio da se utvrdi veza između uslova sinteze, uticaja različitih katjona, strukture i osobina čistih cink-feritnih nanočestica, kao i cink-ferita sa dodatkom indijuma i itrijuma. Radi praćenja uticaja veličine čestica dobijenog praha na strukturu i osobine ovih materijala, sintetisani čist cink-ferit je kalcinisan na različitim temperaturama. Posebno je razmatran i uticaj dodatka različitih jona na distribuciju i preraspodelu katjona u spinelnoj strukturi. Pored toga ispitivan je uticaj tako pripremljenih prahova na njihove magnetne osobine. Rentgenostrukturna i TEM analize potvrdili su da ispitivani uzorci spadaju u klasu nanomaterijala spinelne strukture. Analiza Raman i M&ouml;ssbauer spektara je ukazala na moguću raspodelu katjona između tetraedarskih i oktaedarskih mesta, te formiranje delimično inverznog spinela. Ispitivanja magnetnih osobina su pokazala da histerezisne petlje ne pokazuju saturaciju u prisustvu jakog magnetnog polja, &scaron;to je potvrdilo superparamagnetnu i jednodomensku prirodu čestica. Pokazano je da pored uticaja veličine čestica, dodatak različitih katjona (u ovom slučaju itrijum i indijum) ima veliki uticaj na uređenje strukture, a posledično i na magnetno pona&scaron;anje ispitivanih nanočestičnih sistema.</p> / <p> This thesis presents the results of the investigation of the structural and magnetic properties of nanostructured zinc ferrites, ZnFe2O4 and zinc ferrites supstituted with different amount of indium and yttrium, Zn1-xInxFe2O4 and ZnYxFe2-xO4 (0 &le; x &le; 0,6). Powders based on zinc ferrites were synthesised by a low temperature wet-chemical method &ndash; coprecipitation. The main purpose of this thesis was to establish the relationship between the synthesis, dopants, structure and properties of zinc ferrite based materials. Nanoparticles of ZnFe2O4 were calcined at different temperatures in order to elucidate the influence of the particle size on the magnetic properties of the obtained nanoparticles. In addition, we have investigated the effect of dopant addition on cation distribution in spinel structure, in order to modify the magnetic properties and to obtain the magnetic ceramics with improved properties compared to the bulk-counterparts. The results of X-ray and TEM analyses confirmed the nanosized nature and spinel type structure of the investigated samples. Raman and M&ouml;ssbauer spectroscopy studies implied on the possible cation distribution between the tetrahedral and octahedral sites and formation of the partially inversed spinel. The study of the magnetic properties showed that hysteresis loops do not saturate even in the presence of high magnetic fields, which confirmed the superparamagnetic and single domain nature of the samples. These observations imply that, besides the particle size, doping (e.g. yttrium and indium) causes significant structural rearrangements which in turn induce changes in magnetic behavior of the investigated nanoparticulate systems.</p>