Structural and magnetic properties of FeCoMnCrSi multi-principal alloy

In this study, the magnetic properties of Fe 39.8 Co 19.92 Mn 20.52 Cr 14.77 Si 5 multi-principal element alloy in both bulk and thin films were studied. X-ray diffraction measurements show coexisting face centered cubic (FCC) and hexagonal close packed phases in the bulk and the 500 nm thin films,...

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Veröffentlicht in:	Journal of materials research 2020-04, Vol.35 (8), p.981-989
Hauptverfasser:	Jangid, Rahul, Ainslie, Kenneth B., Kukreja, Roopali
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Sprache:	eng
Schlagworte:	Alloying elements Applied and Technical Physics Biomaterials Cooling Ductility Electronic Face centered cubic lattice Ferromagnetism Film thickness Inorganic Chemistry Magnetic moments Magnetic properties Magnetic saturation Magnetic transitions Magnetism Magnetization Materials Engineering Materials research Materials Science Nanotechnology Photonic and Magnetic Materials Spin glasses Temperature Temperature dependence Thin films Transition temperature
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creator	Jangid, Rahul Ainslie, Kenneth B. Kukreja, Roopali
description	In this study, the magnetic properties of Fe 39.8 Co 19.92 Mn 20.52 Cr 14.77 Si 5 multi-principal element alloy in both bulk and thin films were studied. X-ray diffraction measurements show coexisting face centered cubic (FCC) and hexagonal close packed phases in the bulk and the 500 nm thin films, while only FCC phase is observed in the 65 nm thin film. A four orders of magnitude increase in the magnetic moment is observed for 65 nm thin film compared with the bulk sample. Evolution of magnetization as a function of temperature and applied magnetic field shows multiple magnetic transitions. A paramagnetic to spin glass transition is detected at T S ∼ 390 K for all samples. Further cooling results in a spin glass to ferromagnetic (FM) transition, and the transition temperature, T F , is dependent on the film thickness. Higher saturation magnetization and transition temperature observed for the thin film samples indicate the stabilization of FM ordering due to thickness confinement.
doi_str_mv	10.1557/jmr.2019.405
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X-ray diffraction measurements show coexisting face centered cubic (FCC) and hexagonal close packed phases in the bulk and the 500 nm thin films, while only FCC phase is observed in the 65 nm thin film. A four orders of magnitude increase in the magnetic moment is observed for 65 nm thin film compared with the bulk sample. Evolution of magnetization as a function of temperature and applied magnetic field shows multiple magnetic transitions. A paramagnetic to spin glass transition is detected at T S ∼ 390 K for all samples. Further cooling results in a spin glass to ferromagnetic (FM) transition, and the transition temperature, T F , is dependent on the film thickness. 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subjects	Alloying elements Applied and Technical Physics Biomaterials Cooling Ductility Electronic Face centered cubic lattice Ferromagnetism Film thickness Inorganic Chemistry Magnetic moments Magnetic properties Magnetic saturation Magnetic transitions Magnetism Magnetization Materials Engineering Materials research Materials Science Nanotechnology Photonic and Magnetic Materials Spin glasses Temperature Temperature dependence Thin films Transition temperature
title	Structural and magnetic properties of FeCoMnCrSi multi-principal alloy
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