Your search keyword '"García-Escorial, Asunción"' showing total 5 results

1. Coexistence of antiferro- and ferrimagnetism in the spinel ZnFe2O4 with an inversion degree δ lower than 0.3

Author

Cobos, Miguel Ángel, de la Presa, Patricia, Puente-Orench, Inés, Llorente, Irene, Morales, Irene, García-Escorial, Asunción, Hernando, Antonio, and Jiménez, José Antonio

Published

2022

2. Ferrimagnetic Clusters as the Origin of Anomalous Curie–Weiss Behavior in ZnFe 2 O 4 Antiferromagnetic Susceptibility.

Author

Hernando, Antonio, Cobos, Miguel Ángel, Jiménez, José Antonio, Llorente, Irene, García-Escorial, Asunción, and de la Presa, Patricia

Subjects

AB-initio calculations, MAGNETIC susceptibility, ZINC ferrites, SPINEL group

Abstract

Different studies carried out in the last three decades on the magnetic susceptibility of the spinel ZnFe2O4 ferrite have revealed the positive character of its Curie–Weiss temperature, contradicting its observed antiferromagnetic behavior which is characterized by a well-defined susceptibility peak centered around the Neel temperature (10 K). Some approaches based on ab initio calculations and mixture of interactions have been attempted to explain this anomaly. This work shows how for very low values of the inversion parameter, the small percentage of Fe atoms located in tetrahedral sites gives rise to the appearance of ferrimagnetic clusters around them. Superparamagnetism of these clusters is the main cause of the anomalous Curie–Weiss behavior. This finding is supported experimentally from the thermal dependence of the inverse susceptibility and its evolution with the degree of inversion. [ABSTRACT FROM AUTHOR]

Published

2022

3. Aleaciones cuasicristalinas Al93Fe3Cr2Ti2

Author

García-Escorial, Asunción, Natale, Eduardo, Cremaschi, Victoria J., Todd, Iain, and Lieblich, Marcela

Subjects

Solidificación rápida, lcsh:TN1-997, Aluminio, Nanostructure, Aluminium alloy, Powder metallurgy, Quasicrystal, Nanoestructura, Cuasicristal, Pulvimetalurgia, Rapid solidification, lcsh:Mining engineering. Metallurgy

Abstract

Aluminium alloy powder having a nominal composition of Al93Fe3Cr2Ti2 (at%) has been prepared using gas atomisation. The atomised powder present a microstructure of an aluminium matrix reinforced with a spherical quasicrystalline icosahedral phase, in the range of nanometre in size. The powder was consolidated into bars using warm extrusion. The microstructure of the extruded bars retains the quasicrystalline microstructure and the bars present outstanding mechanical properties, i.e. proof stress of 280 MPa at 300 °C. Upon heating the microstructure evolves towards the equilibrium. The thermal evolution was investigated by means of x-ray diffraction, differential scanning calorimeter, scanning electron microscopy and transmission electron microscopy. According to these observations a transformation in two steps is proposed. A first step consists in the decomposition of the supersaturated solid solution of the matrix and the quasicrystals, and a second step in the transformation of the quasicrystals into the equilibrium phases.Se ha obtenido por atomización por gas polvo de la aleación Al93Fe3Cr2Ti2 (at%). Este polvo presenta una microestructura de una matriz de aluminio reforzada por precipitados icosaédricos de tamaño nanométrico. El polvo fue consolidado por extrusión en forma de barras cilíndricas. La microestructura de las barras retiene la microestructura cuasicristalina de las partículas de polvo. El material consolidado presenta propiedades mecánicas prometedoras, como un límite elástico de 280 MPA a 300 °C. Con los tratamientos térmicos, la microestructura evoluciona hacia el equilibrio. Esta evolución se estudia por difracción de rayos x, calorimetría diferencial de barrido, microscopías electrónicas de barrido y de transmisión. A la luz de los resultados obtenidos se propone que la transformación de las fases con el tiempo de tratamiento térmico ocurre en dos pasos. Primeramente, tiene lugar la descomposición de la solución solida sobresaturada, tanto en la matriz como en los cuasicristales, y posteriormente los cuasicristales se transforman en las fases de equilibrio del sistema: α-Al, Al13Fe4, Al13Cr2 y Al3Ti.

Published

2015

4. Bulk nanostructured aluminium alloy Al93Fe3Cr2Ti2: Processing and characterization

Author

Chlup, Z., Todd, I., García Escorial, Asunción, Lieblich, Marcela, Chlupova, A., and O'Dwyer, J.G.

Abstract

The ability to contro the mechanical of bulk nanostructured aluminium alloys through judicious selection of processing parameters offers the potential for optimised perfomance together with the prospect of producing materiasl based on fitness-for-purpose criteria. In this investigation, nano-quasicrystaline powders of aluminium alloy Al93Fe3Cr2Ti2, were consolidated using extrusion.

Published

2003

5. Unveiling the Hidden Entropy in ZnFe 2 O 4.

Author

Cobos, Miguel Angel, Hernando, Antonio, Marco, José Francisco, Puente-Orench, Inés, Jiménez, José Antonio, Llorente, Irene, García-Escorial, Asunción, and de la Presa, Patricia

Subjects

ENTROPY, MOSSBAUER spectroscopy, MAGNETIC entropy, MAGNETIC properties, UNIT cell, ZINC ferrites

Abstract

The antiferromagnetic (AFM) transition of the normal ZnFe2O4 has been intensively investigated with results showing a lack of long-range order, spin frustrations, and a "hidden" entropy in the calorimetric properties for inversion degrees δ ≈ 0 or δ = 0. As δ drastically impacts the magnetic properties, it is logical to question how a δ value slightly different from zero can affect the magnetic properties. In this work, (Zn1-δFeδ)[ZnδFe2-δ]O4 with δ = 0.05 and δ = 0.27 have been investigated with calorimetry at different applied fields. It is shown that a δ value as small as 0.05 may affect 40% of the unit cells, which become locally ferrimagnetic (FiM) and coexists with AFM and spin disordered regions. The spin disorder disappears under an applied field of 1 T. Mossbauer spectroscopy confirms the presence of a volume fraction with a low hyperfine field that can be ascribed to these spin disordered regions. The volume fractions of the three magnetic phases estimated from entropy and hyperfine measurements are roughly coincident and correspond to approximately 1/3 for each of them. The "hidden" entropy is the zero point entropy different from 0. Consequently, the so-called "hidden" entropy can be ascribed to the frustrations of the spins at the interphase between the AFM-FiM phases due to having δ ≈ 0 instead of ideal δ = 0. [ABSTRACT FROM AUTHOR]

Published

2022