Your search keyword '"magnetic characterization"' showing total 13 results

1. Effect of Ho 3+ Substitution on Magnetic Properties of ZnCr 2 Se 4.

Author

Jendrzejewska, Izabela, Groń, Tadeusz, Tomaszewicz, Elżbieta, Stokłosa, Zbigniew, Goryczka, Tomasz, Goraus, Jerzy, Pilch, Michał, Pietrasik, Ewa, and Witkowska-Kita, Beata

Subjects

*MAGNETIC properties, *HOLMIUM ions, *HOLMIUM, *MAGNETIC moments, *SCANNING electron microscopy, *THERMAL properties, *SUPERPARAMAGNETIC materials

Abstract

A series of ZnCr2−xHoxSe4 microcrystalline spinels (where x = 0.05, 0.075, and 0.10) containing holmium ions in octahedral coordination were obtained by sintering of adequate reactants at high temperatures. The obtained doped materials were characterized by X-ray diffraction, Scanning Electron Microscopy, UV–Vis–NIR, molecular field approximation, and XPS spectroscopies. Their thermal properties were also investigated. The doping of the ZnCr2S4 matrix with paramagnetic Ho3+ ions with a content of not more than 0.1 and a screened 4f shell revealed a significant effect of orbital and Landau diamagnetism, a strong reduction in short-range ferromagnetic interactions, and a broadening and shift of the peak of the first critical field by simultaneous stabilization of the sharp peak in the second critical field. These results correlate well with FPLO calculations, which show that Cr sites have magnetic moments of 3.19 µB and Ho sites have significantly larger ones with a value of 3.95 µB. Zn has a negligible magnetic polarization of 0.02 µB, and Se induces a polarization of approximately −0.12 µB. [ABSTRACT FROM AUTHOR]

Published

2024

2. Electromagnetic Characterization of Silicon–Iron Additively Manufactured Cores for Electric Machines.

Author

Michieletto, Daniele, Alberti, Luigi, Zanini, Filippo, and Carmignato, Simone

Subjects

*ELECTRIC machines, *FERROSILICON, *ELECTRIC motors, *SOFT magnetic materials, *IRON, *SYNCHRONOUS electric motors

Abstract

This paper deals with the electromagnetic characterization of a laminated toroidal ferromagnetic core made through additive manufacturing, specifically using the laser powder bed fusion process. The continuing demand for increasingly efficient, lightweight, and higher performance electric machines is creating huge challenges in the design and realization of new electric motor solutions. The constant improvements in additive manufacturing technologies have prompted researchers to investigate the possibility of adopting these production techniques for the manufacture of high-value electric motors. For these reasons, this paper investigates the ferromagnetic characteristics of an additively manufactured core made with FeSi6.5 powder. The BH curve and the specific iron losses of the processed material have been measured so that they can be compared with a commercial lamination, and have the possibility of carrying out more precise finite element simulations. [ABSTRACT FROM AUTHOR]

Published

2024

3. Characterization of Magnetic and Mineralogical Properties of Slag Particles from WEEE Processing.

Author

Siddique, Asim, Boelens, Peter, Long, Fangchao, Zhou, Shengqiang, Cnudde, Veerle, and Leißner, Thomas

Subjects

*MAGNETIC properties, *ELECTRONIC waste, *MAGNETIC susceptibility, *MAGNETIC fields, *SLAG, *KNOWLEDGE gap theory

Abstract

Magnetic separation has wide-ranging applications in both mineral processing and recycling industries. Nevertheless, its conventional utilization often overlooks the interplay between mineral and particle characteristics and their impact on operational conditions, ultimately influencing the efficacy of the separation process. This work describes a methodology able to achieve the comprehensive characterization and classification of Waste Electrical and Electronic Equipment (WEEE) slag. The primary objective is to establish a meaningful connection between the distinct properties of slag phases and their influence on the separation process. Our methodology consists of several stages. Firstly, the WEEE slag is sieved into distinct size classes, followed by classification into magnetic susceptibility classes by using the Frantz Isodynamic separator. To quantify the magnetic susceptibility of each class, we used a magnetic susceptibility balance, and to identify paramagnetic and ferromagnetic fractions and phases within these magnetic susceptibility classes, we conducted vibrating-sample magnetometer measurements. Finally, to establish a meaningful link between the magnetic characterization, mineralogical, and particle-level details, Mineral Liberation Analysis was conducted for each magnetic susceptibility class. This in-depth analysis, encompassing both particle properties and magnetic susceptibility classes, provides a better understanding of the separation behavior of different phases and can help to enrich phases with a specific range of magnetic susceptibility values. This knowledge advances progress towards the development of predictive separation models that are capable of bridging the gap between theoretical understanding and practical application in the field of magnetic separation. [ABSTRACT FROM AUTHOR]

Published

2023

4. A Simplified Method of the Assessment of Magnetic Anisotropy of Commonly Used Sapphire Substrates in SQUID Magnetometers.

Author

Gas, Katarzyna and Sawicki, Maciej

Subjects

*MAGNETIC anisotropy, *SUBSTRATES (Materials science), *SAPPHIRES, *NANOSTRUCTURED materials, *MAGNETOMETERS

Abstract

Solid-state wafers are indispensable components in material science as substrates for epitaxial homo- or heterostructures or carriers for two-dimensional materials. However, reliable determination of magnetic properties of nanomaterials in volume magnetometry is frequently affected by unexpectedly rich magnetism of these substrates, including significant magnetic anisotropy. Here, we describe a simplified experimental routine of magnetic anisotropy assessment, which we exemplify and validate for epi-ready sapphire wafers from various sources. Both the strength and the sign of magnetic anisotropy are obtained from carefully designed temperature-dependent measurements, which mitigate all known pitfalls of volume SQUID magnetometry and are substantially faster than traditional approaches. Our measurements indicate that in all the samples, two types of net paramagnetic contributions coexist with diamagnetism. The first one can be as strong as 10% of the base diamagnetism of sapphire [−3.7(1) × 10−7 emu/gOe], and when exceeds 2%, it exhibits pronounced magnetic anisotropy, with the easy axis oriented perpendicularly to the face of c-plane wafers. The other is much weaker, but exhibits a ferromagnetic-like appearance. These findings form an important message that nonstandard magnetism of common substrates can significantly influence the results of precise magnetometry of nanoscale materials and that its existence must be taken for granted by both industry and academia. [ABSTRACT FROM AUTHOR]

Published

2022

5. Rapid Characterization Method for SMC Materials for a Preliminary Selection.

Author

Pošković, Emir, Franchini, Fausto, Ferraris, Luca, Carosio, Federico, and Actis Grande, Marco

Subjects

MAGNETIC materials, EDDY current losses, MAGNETIC properties, PHENOLIC resins, SOFT magnetic materials, MANUFACTURING processes, MAGNETS, EPOXY resins

Abstract

In electrical machines, laminated steels are commonly adopted as soft magnetic materials, while for permanent magnets, sintered ferrites and NdFeB are the most common solutions. On the other hand, the growing demand for volume reduction with the increment of efficiency leads to the necessity of exploring other magnetic materials able to face the challenge better than the traditional ones. Bonded magnets have been used to replace sintered magnets, obtaining a better use of space and particular magnetic properties. Instead, for the magnetic circuit, Soft Magnetic Composites (SMC) allow realizing very complex magnetic design (3D path for flux) with iron loss reduction at medium-high frequencies, especially for the eddy currents loss contribution. On the other hand, SMC materials have such drawbacks as low mechanical properties and high hysteresis losses. For this reason, in this work, different studies considering several variables have been carried out. SMCs were produced through a moulding process; inorganic and organic layers to cover ferromagnetic particles were used, adopting different coating processes. Particular tests have been performed for a quicker and more indicative overview of the materials obtained. The single sheet tester (SST) is easier than traditional toroidal methods; on the other hand, the multiplicity of variables affects the SMC materials and their process. For this reason, coercivity and conductibility tests permit rapid measurement and provide a direct classification of the produced SMCs, providing the main information needed to select suitable materials. Results highlighted that choosing the more appropriate SMC material is possible after using these simple preliminary tests. After these tests, it was possible to argue that with 0.2 wt% of phenolic resin as the organic layer (and compaction pressure of 800 MPa), it is possible to produce a good SMC. On the other hand, the SMC with 0.2 wt% of epoxy resin (and compaction pressure of 800 MPa) gives a minor coercivity value. Additionally, despite the SMC with the inorganic layer, 0.2 wt% of nano-ferrites showing the best coercivity values (specifically for vacuum treatment at 600 °C), their resistivity was unsatisfactory. [ABSTRACT FROM AUTHOR]

Published

2021

6. A 3D-Printable Polymer-Metal Soft-Magnetic Functional Composite—Development and Characterization.

Author

Khatri, Bilal, Lappe, Karl, Noetzel, Dorit, Pursche, Kilian, and Hanemann, Thomas

Subjects

*COPOLYMERS, *SOFT magnetic materials, *ACRYLONITRILE butadiene styrene resins, *TENSILE tests, *FLEXURAL strength, *ELASTICITY, *MAGNETIC fields, *MAGNETIC sensors

Abstract

In this work, a 3D printed polymer–metal soft-magnetic composite was developed and characterized for its material, structural, and functional properties. The material comprises acrylonitrile butadiene styrene (ABS) as the polymer matrix, with up to 40 vol. % stainless steel micropowder as the filler. The composites were rheologically analyzed and 3D printed into tensile and flexural test specimens using a commercial desktop 3D printer. Mechanical characterization revealed a linearly decreasing trend of the ultimate tensile strength (UTS) and a sharp decrease in Young’s modulus with increasing filler content. Four-point bending analysis showed a decrease of up to 70% in the flexural strength of the composite and up to a two-factor increase in the secant modulus of elasticity. Magnetic hysteresis characterization revealed retentivities of up to 15.6mT and coercive forces of up to 4.31 kA/m at an applied magnetic field of 485 kA/m. The composite shows promise as a material for the additive manufacturing of passive magnetic sensors and/or actuators. [ABSTRACT FROM AUTHOR]

Published

2018

7. Coercivity and Magnetic Anisotropy of (Fe0.76Si0.09B0.10P0.05)97.5Nb2.0Cu0.5 Amorphous and Nanocrystalline Alloy Produced by Gas Atomization Process

Author

Física aplicada I, Física de materiales, Fisika aplikatua I, Materialen fisika, Alvarez, Kenny L., Martín, José Manuel, Burgos, Nerea, Ipatov, Mihail, Domínguez Carrascoso, María Lourdes, González Estévez, Julián María, Física aplicada I, Física de materiales, Fisika aplikatua I, Materialen fisika, Alvarez, Kenny L., Martín, José Manuel, Burgos, Nerea, Ipatov, Mihail, Domínguez Carrascoso, María Lourdes, and González Estévez, Julián María

Abstract

We present the evolution of magnetic anisotropy obtained from the magnetization curve of (Fe0.76Si0.09B0.10P0.05)97.5Nb2.0Cu0.5 amorphous and nanocrystalline alloy produced by a gas atomization process. The material obtained by this process is a powder exhibiting amorphous character in the as-atomized state. Heat treatment at 480 °C provokes structural relaxation, while annealing the powder at 530 °C for 30 and 60 min develops a fine nanocrystalline structure. Magnetic anisotropy distribution is explained by considering dipolar effects and the modified random anisotropy model.

Published

2020

8. Magnetic Characterization in the Rayleigh Region of Nanocrystalline Magnetic Cores

Author

Física aplicada I, Física de materiales, Fisika aplikatua I, Materialen fisika, Osinalde, Mikel, Infante, Pablo, Domínguez Carrascoso, María Lourdes, Blanco Aranguren, Juan María, Chizhik, Alexander, Zhukova Zhukova, Valentina, Zhukov Egorova, Arkady Pavlovich, González Estévez, Julián María, Física aplicada I, Física de materiales, Fisika aplikatua I, Materialen fisika, Osinalde, Mikel, Infante, Pablo, Domínguez Carrascoso, María Lourdes, Blanco Aranguren, Juan María, Chizhik, Alexander, Zhukova Zhukova, Valentina, Zhukov Egorova, Arkady Pavlovich, and González Estévez, Julián María

Abstract

We report on the structural and magnetic characterization of two nanocrystalline Finemet-type magnetic cores. The nanocrystalline structure developed after annealing the amorphous precursor alloy at 550 degrees C for 30 and 60 min of annealing time. Structural analysis carried out by means of X-ray diffraction providing useful information on the grain size mean and partial volume of the nanocrystalline phase. The magnetic characterization was focused mainly in the Rayleigh region which, influenced by the intergranular coupling, was found to be more efficient in the sample treated for a longer time with a finer nanocrystalline structure.

Published

2018

9. Magnetic Characterization in the Rayleigh Region of Nanocrystalline Magnetic Cores

Author

Valentina Zhukova, Alexander Chizhik, Arcady Zhukov, Mikel Osinalde, Juan Mari Blanco, Lurdes Domínguez, Julian Gonzalez, and Pablo Infante

Subjects

Diffraction, Materials science, Annealing (metallurgy), Alloy, 02 engineering and technology, engineering.material, 01 natural sciences, lcsh:Technology, Article, symbols.namesake, Condensed Matter::Materials Science, 0103 physical sciences, General Materials Science, coercivity, Rayleigh scattering, lcsh:Microscopy, lcsh:QC120-168.85, 010302 applied physics, Condensed matter physics, lcsh:QH201-278.5, lcsh:T, Finemet, Rayleigh region, Coercivity, 021001 nanoscience & nanotechnology, Grain size, Nanocrystalline material, Amorphous solid, lcsh:TA1-2040, engineering, symbols, lcsh:Descriptive and experimental mechanics, lcsh:Electrical engineering. Electronics. Nuclear engineering, grain-size, 0210 nano-technology, lcsh:Engineering (General). Civil engineering (General), magnetic characterization, lcsh:TK1-9971

Abstract

We report on the structural and magnetic characterization of two nanocrystalline Finemet-type magnetic cores. The nanocrystalline structure developed after annealing the amorphous precursor alloy at 550 &deg, C for 30 and 60 min of annealing time. Structural analysis carried out by means of X-ray diffraction providing useful information on the grain size mean and partial volume of the nanocrystalline phase. The magnetic characterization was focused mainly in the Rayleigh region which, influenced by the intergranular coupling, was found to be more efficient in the sample treated for a longer time with a finer nanocrystalline structure.

Published

2018

10. Novel Benchtop Magnetic Particle Spectrometer for Process Monitoring of Magnetic Nanoparticle Synthesis.

Author

Löwa, Norbert, Gutkelch, Dirk, Welge, Ernst-Albrecht, Welz, Roland, Meier, Florian, Baki, Abdulkader, Bleul, Regina, Klein, Thorsten, and Wiekhorst, Frank

Subjects

*MAGNETIC nanoparticles, *MAGNETIC particles, *MAGNETIC spectrometer, *MAGNETIC properties, *MAGNETIC coupling, *MANUFACTURING processes, *MAGNETIC particle imaging

Abstract

Magnetic nanoparticles combine unique magnetic properties that can be used in a variety of biomedical applications for therapy and diagnostics. These applications place high demands on the magnetic properties of nanoparticles. Thus, research, development, and quality assurance of magnetic nanoparticles requires powerful analytical methods that are capable of detecting relevant structural and, above all, magnetic parameters. By directly coupling nanoparticle synthesis with magnetic detectors, relevant nanoparticle properties can be obtained and evaluated, and adjustments can be made to the manufacturing process in real time. This work presents a sensitive and fast magnetic detector for online characterization of magnetic nanoparticles during their continuous micromixer synthesis. The detector is based on the measurement of the nonlinear dynamic magnetic response of magnetic nanoparticles exposed to an oscillating excitation at a frequency of 25 kHz, a technique also known as magnetic particle spectroscopy. Our results underline the excellent suitability of the developed magnetic online detection for coupling with magnetic nanoparticle synthesis based on the micromixer approach. The proven practicability and reliability of the detector for process monitoring forms the basis for further application fields, e.g., as a monitoring tool for chromatographic separation processes. [ABSTRACT FROM AUTHOR]

Published

2020

11. From Single-Core Nanoparticles in Ferrofluids to Multi-Core Magnetic Nanocomposites: Assembly Strategies, Structure, and Magnetic Behavior.

Author

Krasia-Christoforou, Theodora, Socoliuc, Vlad, Knudsen, Kenneth D., Tombácz, Etelka, Turcu, Rodica, and Vékás, Ladislau

Subjects

*MAGNETIC fluids, *IRON oxide nanoparticles, *NANOCOMPOSITE materials, *MAGNETIC fields, *PARTICLE size distribution, *MAGNETIC particles

Abstract

Iron oxide nanoparticles are the basic components of the most promising magnetoresponsive nanoparticle systems for medical (diagnosis and therapy) and bio-related applications. Multi-core iron oxide nanoparticles with a high magnetic moment and well-defined size, shape, and functional coating are designed to fulfill the specific requirements of various biomedical applications, such as contrast agents, heating mediators, drug targeting, or magnetic bioseparation. This review article summarizes recent results in manufacturing multi-core magnetic nanoparticle (MNP) systems emphasizing the synthesis procedures, starting from ferrofluids (with single-core MNPs) as primary materials in various assembly methods to obtain multi-core magnetic particles. The synthesis and functionalization will be followed by the results of advanced physicochemical, structural, and magnetic characterization of multi-core particles, as well as single- and multi-core particle size distribution, morphology, internal structure, agglomerate formation processes, and constant and variable field magnetic properties. The review provides a comprehensive insight into the controlled synthesis and advanced structural and magnetic characterization of multi-core magnetic composites envisaged for nanomedicine and biotechnology. [ABSTRACT FROM AUTHOR]

Published

2020

12. Coercivity and Magnetic Anisotropy of (Fe0.76Si0.09B0.10P0.05)97.5Nb2.0Cu0.5 Amorphous and Nanocrystalline Alloy Produced by Gas Atomization Process.

Author

Alvarez, Kenny L., Martín, José Manuel, Burgos, Nerea, Ipatov, Mihail, Domínguez, Lourdes, and González, Julián

Subjects

*MAGNETIC alloys, *MAGNETIC anisotropy, *AMORPHOUS alloys, *ATOMIZATION, *COERCIVE fields (Electronics), *HEAT treatment

Abstract

We present the evolution of magnetic anisotropy obtained from the magnetization curve of (Fe0.76Si0.09B0.10P0.05)97.5Nb2.0Cu0.5 amorphous and nanocrystalline alloy produced by a gas atomization process. The material obtained by this process is a powder exhibiting amorphous character in the as-atomized state. Heat treatment at 480 °C provokes structural relaxation, while annealing the powder at 530 °C for 30 and 60 min develops a fine nanocrystalline structure. Magnetic anisotropy distribution is explained by considering dipolar effects and the modified random anisotropy model. [ABSTRACT FROM AUTHOR]

Published

2020

13. Magnetic Characterization in the Rayleigh Region of Nanocrystalline Magnetic Cores.

Author

Osinalde, Mikel, Infante, Pablo, Domínguez, Lurdes, Blanco, Juan Mari, Chizhik, Alexander, Zhukova, Valentina, Zhukov, Arcady, and González, Julian

Subjects

*NANOCRYSTALS, *MAGNETIC cores, *RAYLEIGH model, *ANNEALING of crystals, *AMORPHOUS alloys

Abstract

We report on the structural and magnetic characterization of two nanocrystalline Finemet-type magnetic cores. The nanocrystalline structure developed after annealing the amorphous precursor alloy at 550 °C for 30 and 60 min of annealing time. Structural analysis carried out by means of X-ray diffraction providing useful information on the grain size mean and partial volume of the nanocrystalline phase. The magnetic characterization was focused mainly in the Rayleigh region which, influenced by the intergranular coupling, was found to be more efficient in the sample treated for a longer time with a finer nanocrystalline structure. [ABSTRACT FROM AUTHOR]

Published

2018