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2016 | OriginalPaper | Chapter

Magnetic and Transport Properties of M-Cu (M = Co, Fe) Microwires

Authors : A. Zhukov, M. Ipatov, J. J. del Val, M. Ilyn, A. Granovsky, V. Zhukova

Published in: Next Generation Sensors and Systems

Publisher: Springer International Publishing

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Abstract

We report on magnetic, transport and structural properties of Cox-Cu100−x (5 ≤ x ≤ 30) and Fe37Cu63 glass-coated microwires prepared by the Taylor-Ulitovsky method. The objective of the reported work is to develop a novel functional materials exhibiting giant magnetoresistance (GMR). For Co-Cu microwires with x = 5 we observed the resistivity minimum at 40 K associated with the Kondo-like behaviour but magnetoresistance is small. For x ≥ 10 magnetoresistance reaches 9 % at low temperatures. Temperature dependence of susceptibility shows considerable difference for x > 10 and x ≤ 10 attributed to the presence of small Co grains embedded in the Cu matrix for x ≥ 10. By X-ray diffraction we found, that the structure of Cox-Cu100−x microwires for x ≥ 10 is granular consisting of two phases: fcc Cu appearing in all the samples and fcc α-Co presented only in microwires with higher Co content. Structure of Fe37Cu63 microwires consists of Cu nanograins with average grain size of around 40 nm and α-Fe nanocrystals with average grain size ranging between 6 and 45 nm depending on samples geometry. These microwires also exhibit GMR (up to 7.5 % at 5 K).

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Metadata
Title
Magnetic and Transport Properties of M-Cu (M = Co, Fe) Microwires
Authors
A. Zhukov
M. Ipatov
J. J. del Val
M. Ilyn
A. Granovsky
V. Zhukova
Copyright Year
2016
DOI
https://doi.org/10.1007/978-3-319-21671-3_4