Exploring the Different Degrees of Magnetic Disorder in TbRCu Nanoparticle Alloys

Overview

Journal Nanomaterials (Basel)

Date 2020 Oct 31

PMID 33126564

Citations 2

Authors

Elizabeth M Jefremovas

Maria de la Fuente Rodriguez

Javier Alonso

Jesus Rodriguez Fernandez

Jose Ignacio Espeso

Ines Puente-Orench

Daniel P Rojas

Ana Garcia-Prieto

Maria Luisa Fdez-Gubieda

Lidia Rodriguez Fernandez

Luis Fernandez Barquin

Affiliations

Soon will be listed here.

Abstract

Recently, potential technological interest has been revealed for the production of magnetocaloric alloys using Rare-Earth intermetallics. In this work, three series of TbxR1-xCu2 (R ≡ Gd, La, Y) alloys have been produced in bulk and nanoparticle sizes via arc melting and high energy ball milling. Rietveld refinements of the X-ray and Neutron diffraction patterns indicate that the crystalline structure in all alloys is consistent with TbCu2 orthorhombic Imma bulk crystalline structure. The analyses of the DC-magnetisation (MDC) and AC-susceptibility (χAC) show that three distinct degrees of disorder have been achieved by the combination of both the Tb3+ replacement (dilution) and the nanoscaling. These disordered states are characterised by transitions which are evident to MDC, χAC and specific heat. There exists an evolution from the most ordered Superantiferromagnetic arrangement of the Tb0.5La0.5Cu2 NPs with Néel temperature, TN∼ 27 K, and freezing temperature, Tf∼ 7 K, to the less ordered weakly interacting Superparamagnetism of the Tb0.1Y0.9Cu2 nanoparticles (TN absent, and TB∼ 3 K). The Super Spin Glass Tb0.5Gd0.5Cu2 nanoparticles (TN absent, and Tf∼ 20 K) are considered an intermediate disposition in between those two extremes, according to their enhanced random-bond contribution to frustration.

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