Your search keyword '"Zhukova, Valentina"' showing total 278 results

251. Giant magnetoimpedance in thin amorphous and nanocrystalline microwires.

Author

Zhukov, Arcady, Ipatov, Mihail, Talaat, Ahmed, Churyukanova, Margarita, Kaloshkin, Sergei, and Zhukova, Valentina

Subjects

GIANT magnetoimpedance effect, AMORPHOUS substances, NANOCRYSTALS, MAGNETIC fields, MAGNETOELASTIC effects, ELECTRIC impedance

Abstract

We present the results on Giant magneto-impedance effect (GMI) in amorphous and nanocrystalline microwires at frequencies until 4 GHz, paying special attention to tailoring the frequency and magnetic field dependence of the GMI effect. Correlation between magnetoelastic anisotropy and magnetic field dependences of diagonal and off-diagonal impedance components are observed. [ABSTRACT FROM AUTHOR]

Published

2014

252. Manipulation of Magnetic Properties and Domain Wall Dynamics of Amorphous Ferromagnetic Co68.7Fe4Ni1B13Si11Mo2.3 Microwire by Changing of Annealing Temperature

Author

Chichay, Kseniay, Rodionova, Valeria, Ipatov, Mihail, Zhukova, Valentina, and Zhukov, Arkadi

Abstract

This template explains and demonstrates how to prepare your camera-ready paper for Trans Tech Publications. The best is to read these instructions and follow the outline of this text.Please make the page settings of your word processor to A4 format (21 x 29,7 cm or 8 x 11 inches); with the margins: bottom 1.5 cm (0.59 in) and top 2.5 cm (0.98 in), right/left margins must be 2 cm (0.78 in).We shall be able to publish your paper in electronic form on our web page http://www.scientific.net, if the paper format and the margins are correct.Your manuscript will be reduced by approximately 20% by the publisher. Please keep this in mind when designing your figures and tables etc.

Published

2015

253. Effect of applied stresses on domain-wall propagation in glass-coated amorphous microwires.

Author

Blanco, Juan M., Zhukova, Valentina, Ipatov, Mihail, and Zhukov, Arcady

Published

2011

254. Evaluation of use of magnetically bistable microwires for magnetic labels.

Author

Gudoshnikov, Sergey, Usov, Nikolai, Zhukov, Arcady, Zhukova, Valentina, Palvanov, Pavel, Ljubimov, Boris, Serebryakova, Olga, and Gorbunov, Sergey

Published

2011

255. Tuning of Magnetoimpedance Effect and Magnetic Properties of Fe-Rich Glass-Coated Microwires by Joule Heating.

Author

Gonzalez, Alvaro, Zhukova, Valentina, Corte-Leon, Paula, Chizhik, Alexandr, Ipatov, Mihail, Blanco, Juan Maria, and Zhukov, Arcady

Subjects

*MAGNETIC properties, *MAGNETIC anisotropy, *MAGNETIC fields, *MAGNETIC sensors, *HYSTERESIS loop, *STRESS relaxation (Mechanics)

Abstract

The influence of Joule heating on magnetic properties, giant magnetoimpedance (GMI) effect and domain wall (DW) dynamics of Fe75B9Si12C4 glass-coated microwires was studied. A remarkable (up to an order of magnitude) increase in GMI ratio is observed in Joule heated samples in the frequency range from 10 MHz to 1 GHz. In particular, an increase in GMI ratio, from 10% up to 140% at 200 MHz is observed in Joule heated samples. Hysteresis loops of annealed samples maintain a rectangular shape, while a slight decrease in coercivity from 93 A/m to 77 A/m, after treatment, is observed. On the other hand, a modification of MOKE hysteresis loops is observed upon Joule heating. Additionally, an improvement in DW dynamics after Joule heating is documented, achieving DW propagation velocities of up to 700 m/s. GMI ratio improvement along with the change in MOKE loops and DW dynamics improvement have been discussed considering magnetic anisotropy induced by Oersted magnetic fields in the surface layer during Joule heating and internal stress relaxation. A substantial GMI ratio improvement observed in Fe-rich Joule-heated microwires with a rectangular hysteresis loop and fast DW propagation, together with the fact that Fe is a more common and less expensive metal than Co, make them suitable for use in magnetic sensors. [ABSTRACT FROM AUTHOR]

Published

2022

256. Temperature Dependence of the Magnetization Reversal Process and Domain Structure in Fe77.5 - xNixSi7.5B15 MagneticMicrowires.

Author

Olivera, Jesus, Sanchez, Maria Luisa, Prida, Victor M., Varga, Rastislav, Zhukova, Valentina, Zhukov, Arcady P., and Hernando, B.

Subjects

GLASS, CRYSTALS, GLASS coatings, SURFACE coatings, THIN films

Abstract

We have studied the effect of glass coating on the magnetic domain structure and magnetic properties of amorphous glass-coated Fe77.5-xNixSi7.5B15 (x = 0 - 40) microwires. The existence of the radial domain structure is confirmed by the Bitter technique. The stresses introduced by the glass coating increase, when the temperature decreases, changing the domain structure of amorphous microwires. The radial domain structure calculated from the magnetization measurements has a thickness from 5 to 750 nm. Finally, the temperature dependence of the switching field shows the increase of the switching field at low temperatures as a result of the stresses introduced by the glass coating. [ABSTRACT FROM AUTHOR]

Published

2008

257. Development of Co-Rich Microwires with Graded Magnetic Anisotropy.

Author

Zhukova, Valentina, Corte-Leon, Paula, Blanco, Juan Maria, Ipatov, Mihail, Gonzalez, Alvaro, and Zhukov, Arcady

Subjects

*MAGNETIC anisotropy, *MAGNETIC fields, *HYSTERESIS loop, *ANISOTROPY

Abstract

In this paper, a gradual change in the hysteresis loop of Co-rich glass-coated microwire stress-annealed at variable temperature is observed. Such microwires annealed with a temperature gradient also present a variable squareness ratio and magnetic anisotropy field along the microwire's length. The obtained graded anisotropy has been attributed to a gradual modification of the domain structure along the microwire originated by a counterbalance between shape, magnetoelastic, and induced magnetic anisotropies. Accordingly, we propose a rather simple route to design graded magnetic anisotropy in a magnetic microwire. [ABSTRACT FROM AUTHOR]

Published

2022

258. Development of Magnetically Soft Amorphous Microwires for Technological Applications.

Author

Zhukova, Valentina, Corte-Leon, Paula, Blanco, Juan Maria, Ipatov, Mihail, Gonzalez-Legarreta, Lorena, Gonzalez, Alvaro, and Zhukov, Arcady

Subjects

GIANT magnetoimpedance effect, GLASS coatings, MAGNETIC properties, MAGNETOSTRICTION, MAGNETIC anisotropy

Abstract

Amorphous magnetic microwires can be suitable for a variety of technological applications due to their excellent magnetic softness and giant magnetoimpedance (GMI) effect. Several approaches for optimization of soft magnetic properties and GMI effect of magnetic microwires covered with an insulating, flexible, and biocompatible glass coating with tunable magnetic properties are overviewed. The high GMI effect and soft magnetic properties, achieved even in as-prepared Co-rich microwires with a vanishing magnetostriction coefficient, can be further improved by appropriate heat treatment (including stress-annealing and Joule heating). Although as-prepared Fe-rich amorphous microwires exhibit low GMI ratio and rectangular hysteresis loops, stress-annealing, Joule heating, and combined stress-annealed followed by conventional furnace annealing can substantially improve the GMI effect (by more than an order of magnitude). [ABSTRACT FROM AUTHOR]

Published

2022

259. Determination of Magnetic Structures in Magnetic Microwires with Longitudinally Distributed Magnetic Anisotropy.

Author

Chizhik, Alexander, Corte-Leon, Paula, Zhukova, Valentina, Gonzalez, Julian, Gawronski, Przemyslaw, Blanco, Juan Mari, and Zhukov, Arcady

Subjects

*MAGNETIC structure, *MAGNETIZATION reversal, *KERR electro-optical effect, *MAGNETIC properties, *MAGNETIC domain, *MAGNETIC anisotropy

Abstract

We studied the magnetic properties of a glass-covered amorphous microwire that was stress-annealed at temperatures distributed along the microwire length. The Sixtus-Tonks, Kerr effect microscopy and magnetic impedance techniques have been applied. There was a transformation of the magnetic structure across the zones subjected to annealing at different temperatures. The annealing temperature distribution induces the graded magnetic anisotropy in the studied sample. The variety of the surface domain structures depending on the longitudinal location has been discovered. Spiral, circular, curved, elliptic and longitudinal domain structures coexist and replace each other in the process of magnetization reversal. The analysis of the obtained results was carried out based on the calculations of the magnetic structure, assuming the distribution of internal stresses. [ABSTRACT FROM AUTHOR]

Published

2023

260. Effect of Temperature on Magnetoimpedance Effect and Magnetic Properties of Fe- and Co-Rich Glass-Coated Microwires.

Author

Corte-Leon, Paula, Skorvanek, Ivan, Andrejka, František, Jakubcin, Milos, Blanco, Juan Maria, Zhukova, Valentina, and Zhukov, Arcady

Subjects

*GIANT magnetoimpedance effect, *MAGNETIC anisotropy, *MAGNETIC fields, *MAGNETIC hysteresis, *MAGNETIC properties

Abstract

We provide new experimental studies of the temperature dependence of the giant magnetoimpedance (GMI) effect and hysteresis loops of Fe-rich and Co-rich amorphous microwires with rather different room temperature magnetic properties and GMI effect features. We observed a remarkable modification of hysteresis loops and magnetic field dependence of the GMI ratio upon heating in both of the studied samples. We observed a noticeable improvement in the GMI ratio and a change in hysteresis loops from rectangular to inclined upon heating in Fe-rich microwire. However, the opposite trend was observed in Co-rich microwire, in which, upon heating, the shape of the hysteresis loop changed from linear to rectangular. Generally, the evolution of the shape of the hysteresis loops during heating correlates with the modification of the dependencies of the GMI ratio ΔZ/Z on the magnetic field. For Co-rich microwire, the double-peak magnetic field dependence changed to single-peak, while for Fe-rich microwire, the opposite tendency was observed. The origin of the observed temperature dependences of the hysteresis loop and the GMI effect is discussed, considering internal stresses' relaxation during heating, the temperature dependencies of the magnetostriction coefficient, and internal stresses, as well as the Hopkinson effect. [ABSTRACT FROM AUTHOR]

Published

2025

261. Social and Psychological Factors of the Compelled Choice of Profession.

Author

MIRONOVA, Oksana I., PLUZHNIKOVA, Natalya I., AKIMOVA, Natalya N., NEKRASOVA, Marina V., SHAGAEVA, Elena A., and ZHUKOVA, Valentina I.

Subjects

VOCATIONAL guidance, SOCIAL factors, PSYCHOLOGICAL factors, EMPIRICAL research, DECISION making

Abstract

The article analyses the peculiarities of the compelled choice of profession. The results of empirical study revealed its social and psychological factors, in particular: 'Continuation of a professional dynasty', 'Inaccessibility of training', 'Restrictions on health', 'Deficiency of professional kinds of activity in the place of residence' and 'A difficult life situation'. The psychological characteristic of each of the factors is disclosed. During the comparative analysis the gender and age-specific features of the compelled choice of profession are ascertained. Its interrelation with motivation to avoid failures and value orientations of the personality is defined. [ABSTRACT FROM AUTHOR]

Published

2014

262. Optimized 3D Finite-Difference-Time-Domain Algorithm to Model the Plasmonic Properties of Metal Nanoparticles with Near-Unity Accuracy.

Author

Rafiee, Mehran, Chandra, Subhash, Ahmed, Hind, McCormack, Sarah J., Zhukov, Arcady, Perova, Tatiana, and Zhukova, Valentina

Subjects

METAL nanoparticles, FINITE differences, OPTICAL properties, LOTKA-Volterra equations, ELECTRIC fields, ALGORITHMS

Abstract

The finite difference time domain (FDTD) method is a grid-based, robust, and straightforward method to model the optical properties of metal nanoparticles (MNPs). Modelling accuracy and optical properties can be enhanced by increasing FDTD grid resolution; however, the resolution of the grid size is limited by the memory and computational requirements. In this paper, a 3D optimized FDTD (OFDTD) was designed and developed, which introduced new FDTD approximation terms based on the physical events occurring during the plasmonic oscillations in MNP. The proposed method not only required ~52% less memory than conventional FDTD, but also reduced the calculation requirements by ~9%. The 3D OFDTD method was used to model and obtain the extinction spectrum, localized surface plasmon resonance (LSPR) frequency, and the electric field enhancement factor (EF) for spherical silver nanoparticles (Ag NPs). The model's predicted results were compared with traditional FDTD as well as experimental results to validate the model. The OFDTD results were found to be in excellent agreement with the experimental results. The EF accuracy was improved by 74% with respect to FDTD simulation, which helped reaching a near-unity OFDTD accuracy of ~99%. The λ L S P R discrepancy reduced from 20 nm to 3 nm. The EF peak position discrepancy improved from ±5.5 nm to only ±0.5 nm. [ABSTRACT FROM AUTHOR]

Published

2021

263. Angle Magnetization Rotation Method for Characterizing Co-Rich Amorphous Ferromagnetic Microwires.

Author

Gudoshnikov, Sergey, Grebenshchikov, Yury, Popova, Anastasya, Tarasov, Vadim, Gorelikov, Evgeny, Liubimov, Boris, and Zhukova, Valentina

Subjects

MAGNETOSTRICTION, MAGNETIZATION, MAGNETIC fields, MAGNETIZATION reversal, ELECTROMOTIVE force, STRAINS & stresses (Mechanics)

Abstract

A low-frequency model of the magnetization reversal of a microwire is developed for those cases when the microwire magnetization response can go beyond the linear approximation. The analysis of the influence of external magnetic fields on the process of magnetization reversal of the microwire, including the hysteresis mode, was performed. The characteristic dependences of the amplitude of the electromotive force, U2f, arising in the pick-up coil wound around the microwire are obtained. It was established that, in the region of relatively small-acting circular and longitudinal magnetic fields, the U2f signal could have a region with the opposite sign. An extended small-angle magnetization rotation method was used to verify the proposed model and test glass-coated, amorphous, Co-rich microwires. During the experiments, the amplitude of the second harmonic, U2f, arising in the pick-up coil when an alternating electric current with the frequency f flows through the microwire, was measured as a function of the applied longitudinal magnetic field at various mechanical tensile stresses. The effective anisotropy field, the magnetostriction constant, and the residual quenching stress of the investigated microwires were determined by comparing the theoretical and experimental data. [ABSTRACT FROM AUTHOR]

Published

2021

264. Bias Voltage Dependence of Sensing Characteristics in Tunneling Magnetoresistance Sensors.

Author

Wiśniowski, Piotr, Nawrocki, Maciej, Wrona, Jerzy, Cardoso, Susana, Freitas, Paulo. P., and Zhukova, Valentina

Subjects

TUNNEL magnetoresistance, VOLTAGE, MAGNETIC hysteresis, MAGNETORESISTANCE, DETECTORS, MAGNETIC fields

Abstract

One of the characteristic features of tunneling magnetoresistance (TMR) sensors is a strong influence of bias voltage on tunneling current. Since fundamental sensing characteristics of the sensors are primarily determined by the tunneling current, the bias voltage should impact these characteristics. Previous research has indeed showed the influence of the bias voltage on the magnetic field detection and sensitivity. However, the effect has not been investigated for nonlinearity and hysteresis and the influence of bias voltage polarity has not yet been addressed. Therefore, this paper systematically investigates the dependence of field sensitivity, nonlinearity, hysteresis and magnetic field detection of CoFeB/MgO/CoFeB-based magnetoresistance sensors on bias voltage magnitude and polarity. The sensitivity and field detection of all sensors improved significantly with the bias, whereas the nonlinearity and hysteresis deteriorated. The sensitivity increased considerably (up to 32 times) and linearly with bias up to 0.6 V. The field detection also decreased substantially (up 3.9 times) with bias and exhibited the minimum values for the same magnitude under both polarities. Significant and linear increases with bias were also observed for nonlinearity (up to 26 times) and hysteresis (up to 33 times). Moreover, not only the voltage magnitude but also the polarity had a significant effect on the sensing characteristics. This significant, linear and simultaneous effect of improvement and deterioration of the sensing characteristics with bias indicates that both bias voltage magnitude and polarity are key factors in the control and modification of these characteristics. [ABSTRACT FROM AUTHOR]

Published

2021

265. Ceramic-Chromium Hall Sensors for Environments with High Temperatures and Neutron Radiation.

Author

Entler, Slavomir, Soban, Zbynek, Duran, Ivan, Kovarik, Karel, Vyborny, Karel, Sebek, Josef, Tazlaru, Stana, Strelecek, Jan, Sladek, Petr, and Zhukova, Valentina

Subjects

NEUTRON temperature, HIGH temperatures, NUCLEAR fusion, DETECTORS, FUSION reactors, RADIATION, FUSION reactor divertors

Abstract

Ceramic-chromium Hall sensors represent a temperature and radiation resistant alternative to Hall sensors based on semiconductors. Demand for these sensors is presently motivated by the ITER and DEMO nuclear fusion projects. The developed ceramic-chromium Hall sensors were tested up to a temperature of 550 °C and a magnetic field of 14 T. The magnitude of the sensitivity of the tested sensor was 6.2 mV/A/T at 20 °C and 4.6 mV/A/T at 500 °C. The sensitivity was observed to be weakly dependent on a temperature above 240 °C with an average temperature coefficient of 0.014%/°C and independent of the magnetic field with a relative average deviation below the measurement accuracy of 0.086%. A simulation of a neutron-induced transmutation was performed to assess changes in the composition of the chromium. After 5.2 operational years of the DEMO fusion reactor, the transmuted fraction of the chromium sensitive layer was found to be 0.27% at the most exposed sensor location behind the divertor cassette with a neutron fluence of 6.08 × 1025 n/m2. The ceramic-chromium Hall sensors show the potential to be suitable magnetic sensors for environments with high temperatures and strong neutron radiation. [ABSTRACT FROM AUTHOR]

Published

2021

266. Tuning of magnetic properties in Ni-Mn-Ga Heusler-type glass-coated microwires by annealing.

Author

Garcia, Carlos, Zhukova, Valentina, Shevyrtalov, Sergey, Ipatov, Mihail, Corte-Leon, Paula, and Zhukov, Arcady

Subjects

*MAGNETIC properties, *MAGNETIC transitions, *HEUSLER alloys, *MAGNETIC fields, *MAGNETIC moments, *CURIE temperature

Abstract

In this work, we studied the magnetic properties of as-prepared and annealed Ni-Mn-Ga Heusler alloy glass-covered microwires. We observed that the annealing conditions strongly affect the magnetic field dependencies of magnetic moments, the temperature dependence of the magnetization, and the Curie temperature of microwires. By mixing the microwires annealed at different temperatures, we achieved the broadening of the second-order phase transition. Image 1 • Influence of annealing on Curie temperature of NiMnGa microwires. • Observation of second-order magnetic transition near room temperature in annealed NiMnGa microwires. • Significant difference in ZFC-FC curves attributed to the rather inhomogeneous structure of annealed NiMnGa microwires. • Broadening of the second-order phase transition achieved by mixing the microwires annealed at different temperatures. [ABSTRACT FROM AUTHOR]

Published

2020

267. Bending annealing induced transformation of magnetic structure in Co-rich amorphous microwires.

Author

Chizhik, Alexander, Corte-Leon, Paula, Zhukova, Valentina, and Zhukov, Arcady

Subjects

*MAGNETIC structure, *BENDING stresses, *SOFT magnetic materials, *STRESS concentration, *SURFACE structure, *MAGNETIC domain

Abstract

For the first time, the magnetic structure of a glass-coated microwire, previously subjected to bending annealing was investigated. Magnetic and magneto-optical analyses were performed after the sample was annealed and returned to a straightened state. Changes in the magnetic structure, induced by the bending annealing, were observed both within the microwire and on its surface. The spatial distribution of the magnetic structure was primarily attributed to the spatial distribution of the stress gradient resulting from bending stress. Special emphasis was placed on the transformation of surface domain structures, with the diversity of these structures indicating a significant influence of bending-annealing-unbending procedure on their formation process. [ABSTRACT FROM AUTHOR]

Published

2024

268. Fabrication and First Characterization of Ni2MnGa Glass-Coated Microwires

Author

Varga, R., Ryba, T., Saksl, Karel, Zhukova, Valentina, and Zhukov, Arcady

Abstract

In this paper we report on fabrication and characterization of a novel glass coated Ni2MnGa glass coated microwires with metallic nucleus diameter of 44 μm prepared the modified Taylor-Ulitovsky method. First magnetic and structural characterization have been performed.

Published

2011

269. Search for B- -> mu(-)(nu)over-bar(mu) Decays at the Belle Experiment

Author

Sibidanov, A., Varvell, K. E., Adachi, I., Aihara, H., Al Said, S., Garmash, A., Goldenzweig, P., Greenwald, D., Asner, D. M., Aushev, T., Ayad, R., Babu, V., Badhrees, I., Bahinipati, S., Bakich, A. M., Bansal, V., Barberio, E., Behera, P., Bhuyan, B., Biswal, J., Bozek, A., Bracko, M., Browder, T. E., Cervenkov, D., Chang, P., Chekelian, V., Chen, A., Cheon, B. G., Chilikin, K., Cho, K., Choi, S. K., Choi, Y., Cinabro, D., Czank, T., Dash, N., Di Carlo, S., Dolezal, Z., Drasal, Z., Dutta, D., Eidelman, S., Epifanov, D., Fast, J. E., Ferber, T., Fulsom, B. G., Gaur, V., Gabyshev, N., Guan, Y., Guido, E., Haba, J., Hayasaka, K., Hayashii, H., Hedges, M. T., Hirose, S., Hou, W. S., Hsu, C. L., Iijima, T., Inami, K., Inguglia, G., Ishikawa, A., Itoh, R., Iwasaki, M., Iwasaki, Y., Jacobs, W. W., Jaegle, I., Jeon, H. B., Jin, Y., Joo, K. K., Julius, T., Kahn, J., Kaliyar, A. B., Kang, K. H., Karyan, G., Kawasaki, T., Kiesling, C., Kim, D. Y., Kim, J. B., Kim, S. H., Kim, Y. J., Kinoshita, K., Kodys, P., Korpar, S., Kotchetkov, D., Krizan, P., Krokovny, P., Kuhr, T., Kulasiri, R., Kumar, R., Kuzmin, A., Kwon, Y. J., Lange, J. S., Lee, I. S., Li, C. H., Li, L., Gioi, L. Li, Libby, J., Liventsev, D., Lubej, M., Luo, T., Masuda, M., Matsuda, T., Merola, M., Miyabayashi, K., Miyata, H., Mizuk, R., Mohanty, G. B., Moon, H. K., Mori, T., Mussa, R., Nakano, E., Nakao, M., Nanut, T., Nath, K. J., Natkaniec, Z., Nayak, M., Niiyama, M., Nisar, N. K., Nishida, S., Ogawa, S., Okuno, S., Ono, H., Pakhlov, P., Pakhlova, G., Pal, B., Park, C. S., Park, C. W., Park, H., Paul, S., Pedlar, T. K., Pestotnik, R., Piilonen, L. E., Ritter, M., Rostomyan, A., Rozanska, M., Sakai, Y., Salehi, M., Sandilya, S., Sato, Y., Savinov, V., Schneider, O., Schnell, Gunar, Schwanda, C., Seino, Y., Senyo, K., Sevior, M. E., Shebalin, V., Shen, C. P., Shibata, T. A., Shiu, J. G., Simon, F., Sokolov, A., Solovieva, E., Staric, M., Strube, J. F., Stypula, J., Sumihama, M., Sumisawa, K., Sumiyoshi, T., Takizawa, M., Tamponi, U., Tanida, K., Tenchini, F., Trabelsi, K., Uchida, M., Uehara, S., Uglov, T., Unno, Y., Uno, S., Urquijo, P., Van Hulse, Charlotte Barbara, Varner, G., Vorobyev, V., Wang, C. H., Wang, M. Z., Wang, P., Watanabe, M., Watanuki, S., Widmann, E., Won, E., Yamashita, Y., Ye, H., Yelton, J., Yuan, C. Z., Yusa, Y., Zhang, Z. P., Zhilich, V., Zhukova Zhukova, Valentina, Zhulanov, V., Zupanc, A., and Belle Collaboration

Subjects

monte-carlo, identification, High Energy Physics::Experiment, Monte-Carlo, kekb, KEKB

Abstract

We report the results of a search for the rare, purely leptonic decay B- -> mu(-)(nu) over bar (mu) performed with a 711 fb(-1) data sample that contains 772 x 10(6) B (B) over bar pairs, collected near the Upsilon(4S) resonance with the Belle detector at the KEKB asymmetric-energy e(+)e(-) collider. The signal events are selected based on the presence of a high momentum muon and the topology of the rest of the event showing properties of a generic B-meson decay, as well as the missing energy and momentum being consistent with the hypothesis of a neutrino from the signal decay. We find a 2.4 standard deviation excess above background including systematic uncertainties, which corresponds to a branching fraction of B(B- -> mu(-)(nu) over bar (mu)) = (6.46 +/- 2.22 +/- 1.60) x 10(-7) or a frequentist 90% confidence level interval on the B- -> mu(-)(nu) over bar (mu) branching fraction of [2.9, 10.7] x 10(-7). We thank the KEKB group for the excellent operation of the accelerator; the KEK cryogenics group for the efficient operation of the solenoid; and the KEK computer group, the National Institute of Informatics, and the Pacific Northwest National Laboratory (PNNL) Environmental Molecular Sciences Laboratory (EMSL) computing group for valuable computing and Science Information NETwork 5 (SINET5) network support. We acknowledge support from the Ministry of Education, Culture, Sports, Science, and Technology (MEXT) of Japan, the Japan Society for the Promotion of Science (JSPS), and the Tau-Lepton Physics Research Center of Nagoya University; the Australian Research Council including Grants No. DP180102629, No. DP170102389, No. DP170102204, No. DP150103061, No. FT130100303; Austrian Science Fund under Grant No. P 26794-N20; the National Natural Science Foundation of China under Contracts No. 11435013, No. 11475187, No. 11521505, No. 11575017, No. 11675166, No. 11705209; Key Research Program of Frontier Sciences, Chinese Academy of Sciences (CAS), Grant No. QYZDJ-SSW-SLH011; the CAS Center for Excellence in Particle Physics (CCEPP); Fudan University Grants No. JIH5913023, No. IDH5913011/003, No. JIH5913024, No. IDH5913011/002; the Ministry of Education, Youth and Sports of the Czech Republic under Contract No. LTT17020; the Carl Zeiss Foundation, the Deutsche Forschungsgemeinschaft, the Excellence Cluster Universe, and the VolkswagenStiftung; the Department of Science and Technology of India; the Istituto Nazionale di Fisica Nucleare of Italy; National Research Foundation (NRF) of Korea Grants No. 2014R1A2A2A01005286, No. 2015R1A2A2A01003280, No. 2015H1A2A1033649, No. 2016R1D1A1B01010135, No. 2016K1A3A7A09005603, and No. 2016R1D1A1B02012900; Radiation Science Research Institute, Foreign Large-size Research Facility Application Supporting project and the Global Science Experimental Data Hub Center of the Korea Institute of Science and Technology Information; the Polish Ministry of Science and Higher Education and the National Science Center; the Ministry of Education and Science of the Russian Federation and the Russian Foundation for Basic Research; the Slovenian Research Agency; Ikerbasque, Basque Foundation for Science, Basque Government (No. IT956-16) and Ministry of Economy and Competitiveness (MINECO) (Juan de la Cierva), Spain; the Swiss National Science Foundation; the Ministry of Education and the Ministry of Science and Technology of Taiwan; and the United States Department of Energy and the National Science Foundation.

270. Anomalous Magnetic Anisotropy Behaviour in Co-Rich and Fe-Rich Glass-Coated Microwires under Applied Stress.

Author

García-Gómez, Alfonso, Blanco, Juan María, Corte-León, Paula, Ipatov, Mihail, González, Álvaro, González, Julián, Zhukov, Arcady, and Zhukova, Valentina

Subjects

*MAGNETOSTRICTION, *MAGNETIC properties, *SOFT magnetic materials, *MAGNETIC anisotropy

Abstract

In this article, we study the effect of annealing temperature and applied stress on the magnetic properties of Fe 71.80 B 13.27 Si 11.02 Nb 2.99 Ni 0.92 and Co 65.34 Si 12.00 B 10.20 Cr 8.48 Fe 3.90 Mo 0.08 microwires. An anomalous behavior of the coercive field is observed while applying stress, indicating nontrivial changes in the microwire magnetic anisotropy. The effect of applied stimuli on the magnetic anisotropy and magnetostriction constant in both microwires is also discussed. [ABSTRACT FROM AUTHOR]

Published

2023

271. Carbon-Doped Co 2 MnSi Heusler Alloy Microwires with Improved Thermal Characteristics of Magnetization for Multifunctional Applications.

Author

Salaheldeen, Mohamed, Wederni, Asma, Ipatov, Mihail, Zhukova, Valentina, and Zhukov, Arcady

Subjects

*HEUSLER alloys, *MAGNETIC structure, *MAGNETIZATION, *CARBON dioxide, *STRAINS & stresses (Mechanics), *MAGNETIC entropy

Abstract

In the current work, we illustrate the effect of adding a small amount of carbon to very common Co2MnSi Heusler alloy-based glass-coated microwires. A significant change in the magnetic and structure structural properties was observed for the new alloy Co2MnSiC compared to the Co2MnSi alloy. Magneto-structural investigations were performed to clarify the main physical parameters, i.e., structural and magnetic parameters, at a wide range of measuring temperatures. The XRD analysis illustrated the well-defined crystalline structure with average grain size (Dg = 29.16 nm) and a uniform cubic structure with A2 type compared to the mixed L21 and B2 cubic structures for Co2MnSi-based glass-coated microwires. The magnetic behavior was investigated at a temperature range of 5 to 300 K and under an applied external magnetic field (50 Oe to 20 kOe). The thermomagnetic behavior of Co2MnSiC glass-coated microwires shows a perfectly stable behavior for a temperature range from 300 K to 5 K. By studying the field cooling (FC) and field heating (FH) magnetization curves at a wide range of applied external magnetic fields, we detected a critical magnetic field (H = 1 kOe) where FC and FH curves have a stable magnetic behavior for the Co2MnSiC sample; such stability was not found in the Co2MnSi sample. We proposed a phenomenal expression to estimate the magnetization thermal stability, ΔM (%), of FC and FH magnetization curves, and the maximum value was detected at the critical magnetic field where ΔM (%) ≈ 98%. The promising magnetic stability of Co2MnSiC glass-coated microwires with temperature is due to the changing of the microstructure induced by the addition of carbon, as the A2-type structure shows a unique stability in response to variation in the temperature and the external magnetic field. In addition, a unique internal mechanical stress was induced during the fabrication process and played a role in controlling magnetic behavior with the temperature and external magnetic field. The obtained results make Co2MnSiC a promising candidate for magnetic sensing devices based on Heusler glass-coated microwires. [ABSTRACT FROM AUTHOR]

Published

2023

272. Enhancing the Squareness and Bi-Phase Magnetic Switching of Co 2 FeSi Microwires for Sensing Application.

Author

Salaheldeen, Mohamed, Wederni, Asma, Ipatov, Mihail, Zhukova, Valentina, Lopez Anton, Ricardo, and Zhukov, Arcady

Subjects

*MAGNETIC control, *REMANENCE, *MAGNETIC domain, *MAGNETIC structure, *MAGNETIC properties

Abstract

In the current study we have obtained Co2FeSi glass-coated microwires with different geometrical aspect ratios, ρ = d/Dtot (diameter of metallic nucleus, d and total diameter, Dtot). The structure and magnetic properties are investigated at a wide range of temperatures. XRD analysis illustrates a notable change in the microstructure by increasing the aspect ratio of Co2FeSi-glass-coated microwires. The amorphous structure is detected for the sample with the lowest aspect ratio (ρ = 0.23), whereas a growth of crystalline structure is observed in the other samples (aspect ratio ρ = 0.30 and 0.43). This change in the microstructure properties correlates with dramatic changing in magnetic properties. For the sample with the lowest ρ-ratio, non-perfect square loops are obtained with low normalized remanent magnetization. A notable enhancement in the squareness and coercivity are obtained by increasing ρ-ratio. Changing the internal stresses strongly affects the microstructure, resulting in a complex magnetic reversal process. The thermomagnetic curves show large irreversibility for the Co2FeSi with low ρ-ratio. Meanwhile, if we increase the ρ-ratio, the sample shows perfect ferromagnetic behavior without irreversibility. The current result illustrates the ability to control the microstructure and magnetic properties of Co2FeSi glass-coated microwires by changing only their geometric properties without performing any additional heat treatment. The modification of geometric parameters of Co2FeSi glass-coated microwires allows to obtain microwires that exhibit an unusual magnetization behavior that offers opportunities to understand the phenomena of various types of magnetic domain structures, which is essentially helpful for designing sensing devices based on thermal magnetization switching. [ABSTRACT FROM AUTHOR]

Published

2023

273. Tunable domain wall dynamics in amorphous ferromagnetic microwires.

Author

Chichay, Ksenia, Rodionova, Valeria, Zhukova, Valentina, Ipatov, Mikhail, Perov, Nikolai, Gorshenkov, Mikhail, Andreev, Nikolay, and Zhukov, Arkady

Subjects

*DOMAIN walls (String models), *MAGNETOSTRICTION, *MAGNETIC domain walls, *DOMAIN walls (Ferromagnetism), *TRANSITION metals

Abstract

In this work, we show the possibility of tuning the domain wall dynamics in amorphous ferromagnetic microwires by means of thermal annealing. We investigate the effect of annealing time and temperature on the field dependence of the domain wall velocity in magnetically bistable Fe- and CoFeNi-based microwires. We demonstrate that the magnitude of the magnetostriction coefficient determines the tendency of the domain wall mobility and velocity change and we relate the magnetostriction coefficient to the stress relaxation upon annealing. Thus, in the case of Fe-based microwires with large positive magnetostriction ∼10−6 the stress relaxation caused by the annealing leads to an increase of the velocity and mobility of the domain wall, while the same parameters of the domain wall dynamics for CoFeNi-based microwires with nearly zero magnetostriction coefficient ∼10−7-10−8 significantly decrease. Growth of the minimum magnetic field for domain wall propagation upon annealing is observed in CoFeNi microwires with vanishing magnetostriction coefficient. This influence of annealing on the domain wall dynamics of CoFeNi microwires is explained by considering domain wall stabilization due to pair ordering. The opposite tendency observed for Fe-based microwires with only one transition metal is associated with the stress relaxation upon annealing. Image 1 • Magnetostriction value influences on the domain wall dynamics change after annealing. • Stress relaxation causes increase of the domain wall velocity in Fe-based microwires. • Annealing leads to the magnetostriction growth in FeCoNi-based microwires. • Domain wall velocity decreases after annealing for FeCoNi-based microwires. [ABSTRACT FROM AUTHOR]

Published

2020

274. Modern advances in glass-coated microwires: A significant distinction as a soft magnet

Author

Talaat Farag Ibrahim Eladawi, Ahmed, Zhukova Zhukova, Valentina, Zhukov Egorova, Arkady Pavlovich, Física de Materiales, Materialen Fisika, and Zhukov Egorova, Arcady Pavlovich

Subjects

magnetism, propiedades magnéticas, magnetic properties, magnetismo

Abstract

174 p., Esta tesis doctoral se ha dedicado a los modernos avances en los estudios de microhilos con recubrimiento de capa vítrea que representen una clase especial de vidrios metálicos. Estos microhilos magnéticos proporcionan un amplio campo para estudios fundamentales de muchos fenómenos físicos, que no serían fáciles de estudiar en otro tipo de materiales magnéticos convencionales. Sus propiedades magnéticas junto con su pequeño diámetro, los hacen candidatos muy prometedores para nuevas aplicaciones.Los microhilos con recubrimiento de capa vítrea, fabricados mediante la técnica modificada de Taylor-Ulitovsky basada en un enfriamiento rápido de la aleación fundida, se definen como un material compuesto de un núcleo metálico cubierto por una capa de vidrio. Una de las características más atractivas de estos microhilos es la técnica de fabricación. Esta técnica consiste en la obtención por solidificación ultrarrápida de un microhilo compuesto simultáneamente de un núcleo ferro-magnético metálico de la aleación fundida recubierto con una capa vítrea mediante un enfriamiento ultrarrápido desde el estado fundido. Por lo tanto, las diferencias entre los coeficientes de dilatación térmica del núcleo metálico y del vidrio dan como resultado la aparición de grandes tensiones internas, lo cual influye en las características magnéticas de estos materiales. Por otro lado, debido a la ausencia de anisotropía magnetocristalina, las propiedades magnéticas de un microhilo totalmente amorfo se determinan predominantemente por la energía magnetoelástica determinada por la magnetización espontánea (momentos magnéticos locales) y las tensiones internas. En consecuencia, la atención principal para controlar las propiedades magnéticas de los microhilos se orienta a su anisotropía magnetoelástica, Kme. A este respecto, las principales posibilidades para modificar las propiedades magnéticas de microhilos amorfos son a través de la manipulación entre las tensiones internas y la selección adecuada de la composición química del núcleo metálico (controlar la magnetostricción).Por lo tanto, modificando el espesor del vidrio, se podría controlar las tensiones internas, y correspondientemente, las características magnéticas variarían en función de la relación entre los diámetros del núcleo y de la capa vítrea del microhilo. De forma paralela, dependiendo de la composición de la aleación química el valor de la magnetostricción varía, y por lo tanto, se abren líneas de investigaciones para sintonizar las respuestas magnéticas o las propiedades estructurales de microhilos que tienen las mismas dimensiones pero con diferentes composiciones químicas.Esta tesis doctoral estudia las novedosas características de los microhilos magnéticamente blandos desde el punto de vista de tres perspectivas: (i) controlar los valores de la tensión interna a través de la modificación del diámetro del núcleo metálico y/o el espesor de la capa vítrea. (ii) obtener un estado nanocristalino de dos fases: una de pequeños cristales de tamaño nano incrustadas en una matriz amorfa. (iii) el control de las condiciones del tratamiento térmico antes de la formación de fases cristalinas, es decir, cuando se relajan las tensiones internas después del proceso de fabricación. El desarrollo del trabajo realizado se divide en dos partes de 4 capítulos cada una. La primera parte, comienza con una introducción general y la historia de los vidrios metálicos hasta llegar a los microhilos. El capítulo 2 de la primera parte se exponen los parámetros que determinan el comportamiento magnético/estructural de los microhilos. A continuación, en los capítulos 3 y 4, se describe el interés tecnológico y las técnicas experimentales que han sido utilizadas para estudiar las propiedades de los microhilos magnéticos. Por último, en la segunda parte, se describen, los principales resultados que se han obtenido a lo largo de 4 capítulos.Parte IICapítulo 1A lo largo del primer capítulo, hemos comprobado experimentalmente la correlación directa entre el efecto de nanocristalización y las propiedades magnéticas. Para ello, se ha realizado una investigación sistemática en tres composiciones de aleación de tipo FINEMET con diferentes diámetros de núcleo metálico o espesor del vidrio. Principalmente de nuestros estudios se ha logrado optimizar un campo coercitivo alrededor de 10 A/m correspondiente a un tamaño de grano ultrafino de 11 nm en muestras recocidas a Tann = 550°C. Además, hemos detectado un valor de 125% de GMI observado a f = 500 MHz lo que supone una gran mejora respecto a la pobre respuesta de las muestras amorfas (as-cast) (1% de GMI). El aumento del valor las tensiones internas está en conexión con la anisotropía magnetoelástica: un alto valor de la anisotropía, se corresponde con la ¿-proporción más baja. En consecuencia, el campo coercitivo de los microhilos, tanto sean muestras as-cast como recocidas, resulta de ser muy sensible a la relación-¿.Por otro lado, se ha observado una diferencia significativa en el comportamiento magnético en los procesos de desvitrificación debido a la formación de pequeños cristales de fase ¿-Fe-Si en la primera etapa de nanocristalización (Tann = 550°C) o por la precipitación de la fase Fe2B a altas temperaturas (más de 650°C). También, hemos observado, que el control de la velocidad de enfriamiento rápido durante el proceso de fabricación afecta fuertemente a la estructura final de los microhilos producidos. Consecuentemente, una estructura nanocristalina de aproximadamente 12 nm de tamaño grano con una fase ¿-Fe-Si y un campo coercitivo de 12 A/m se han obtenido a partir del tratamiento de muestras as-cast lo que ha dado lugar a un considerable aumento del valor de GMI de hasta 50%. Además, se produce un cambio drástico en los coeficientes de la magnetostricción después de la nanocristalización: los valores de magnetostricción cambian de positivas a casi nulas. Estos resultados hacen de estos microhilos unos buenos candidatos para aplicaciones basadas en el efecto GMI.Capítulo 2El capitulo 2 incluye la investigación magnética y estructural de nuevos microhilos de aleación de tipo HITPERM y el efecto de añadir 1% de Cu. El análisis estructural de las muestras as-cast resulta muestra la presencia de una estructura nanocristalina que consiste en granos de aproximadamente 23 nm de la fase BCC ¿-FeCo B2 ordenada y una fase amorfa, obtenidos directamente sin tratamientos térmicos. Se ha observado un comportamiento bastante anómalo tras el tratamiento térmico: el tamaño de grano bajó hasta 11 nm en lugar de subir. Hemos explicado este comportamiento teniendo en cuenta el crecimiento cristalino limitado por la composición química. Además, después del recocido podría consistir en un proceso de nucleación múltiple con la formación pequeños granos. Esta misma masiva nucleación de pequeños granos dio como resultado una disminución del tamaño de grano promedio calculado después del recocido. La presencia de dos fases estructurales ha sido confirmado por la dependencia de la imanación M(T) con la temperatura, donde se observó una disminución notable de la imanación al aumentar la temperatura lo que indica la existencia de dos temperaturas de Curie, una de la fase amorfa y otra de la fase nanocristalina.Los ciclos de histéresis de todas las muestras presentan forma rectangular, tanto as-cast como recocidas, lo que nos permitió investigar los procesos de inversión de la magnetización y la dinámica de la pared de dominio. Un cambio drástico de las propiedades magnéticas: cambio de la dinámica de la pared, y de la dependencia de la frecuencia del campo switching se han observado después del recocido. Los cambios observados en las propiedades magnéticas se han justificado teniendo en cuenta la relajación estructural de dichos granos con magnetostricción alta positiva. Unas velocidades bastante rápidas de la pared magnética han sido observadas en muestras as-cast alcanzando valores tan rápidos como 1.2 Km/s. Además, la disminución de la anisotropía magnetoelástica después del recocido junto con la relajación de la tensión interna dio como resultado una mejorara de la velocidad de la pared así como de su movilidad. El desarrollo de las propiedades magnéticas de los mirohilos de tipo HITPERM puede servir para aplicaciones tecnológicas en las que se requieren procesos de magnetización rápida.Capítulo 3El capítulo 3 se ha demostrado, experimentalmente, que las propiedades magnéticas de los microhilos amorfos ricos en Co, pueden ser modificadas después del tratamiento térmico adecuado. Recocidos convencionales, sin tensión y con tensión, han afectado considerablemente a los ciclos de histéresis, al efecto GMI, y a la dinámica de la pared magnética. Todas las dependencias observadas han sido justificadas considerando la relajación de las tensiones internas y el cambio de la magnetostricción después del tratamiento. Además, en ciertas condiciones de recocido observamos coexistencia de efecto GMI y rápida propagación de la pared en la misma muestra recocida. Por otra parte, después del recocido, para ciertas condiciones, se observó un aumento de la velocidad de pared al aplicar una tensión externa.Capítulo 4Por primera vez, se ha llevado a cabo un estudio sistemático de la eficiencia de los microhilos amorfos ricos en Fe para terapia de hipertermia magnética. Hemos aportado notables ideas para desarrollar el potencial de estos microhilos en las previsibles tendencias en aplicaciones de hipertermia. Concretamente, hemos demostrado respuestas de calentamiento apreciables en el que el intervalo terapéutico (40-45ºC) para el tratamiento del cáncer se puede alcanzar fácilmente a los pocos minutos de calentamiento.Hemos encontrado que estos microhilos presentan una alta eficiencia de calentamiento cuando se exponen a un campo magnético alterno. Solamente un trozo de 5 mm de longitud es capaz de alcanzar un valor de SAR considerablemente elevado de hasta 553 W/g, gracias a su ciclo de histéresis rectangular y a su característica estructura de dominios magnéticos. La interacción entre dos microhilos da lugar a un mejor calentamiento, alcanzándose valores de SAR de hasta 950 W/g. Además, hemos encontrado una fuerte correlación entre el número de microhilos y la eficiencia de calentamiento de las muestras estudiadas. A este respecto, hemos observado que reduciendo la separación entre microhilos mejora significativamente los valores de SAR debido a la interacción magnetostática entre los mismos. También, hemos analizado el efecto de la alineación del microhilo con respecto a la dirección del campo magnético aplicado. En estas ocasiones, hemos determinado que la orientación paralela a la dirección del campo magnético es la mejor disposición para aumentar el valor de SAR.Por otro lado, el calentamiento total generado por los microhilos estudiados, ha demostrado un proceso adiabático donde no ocurrió ninguna transferencia de calor entre el sistema empleado y su entorno, lo que confirma que los microhilos a base de Fe son muy eficientes en la transferencia de calor de forma homogénea. Además, la capa vítrea se puede considerar como una barrera aislante, y por lo tanto, mejora la compatibilidad de esta familia de materiales para aplicaciones biomédicas. A tenor de estos resultados, podemos afirmar que nuestro estudio pone de relieve la importancia de investigar nuevos materiales para tratamientos de hipertermia magnética.

Published

2016

275. Spiral Annealing of Magnetic Microwires.

Author

Chizhik A, Corte-Leon P, Zhukova V, Blanco JM, Gonzalez J, and Zhukov A

Abstract

A preprocessing technique named "spiral annealing" was applied for the first time to magnetic microwires. In this process, the sample was arranged in a flat spiral shape during annealing, and subsequent measurements were conducted on the unbent sample with the induced stress distribution along and transverse to the sample. The research utilized both magnetic and magneto-optical methods. The anisotropy field magnitude in both the volume and surface of the microwire was measured, and for the first time, a direct correlation between the anisotropy field and the curvature of a spirally annealed microwire was established. Additionally, a connection between the type of surface domain structure and the degree of spiral curvature was identified. The preservation of the distribution of spiral annealing-induced magnetic properties both along and across the microwire is a key effect influencing the technological application of the microwire. The range of induced curvature within which a specific helical magnetic structure can exist was also determined. This insight links the conditions of spiral annealing to the selection of microwires as active elements in magnetic sensors.

Published

2024

276. Dependence of Magnetic Properties of As-Prepared Nanocrystalline Ni 2 MnGa Glass-Coated Microwires on the Geometrical Aspect Ratio.

Author

Salaheldeen M, Zhukova V, Lopez Anton R, and Zhukov A

Abstract

We have prepared NiMnGa glass-coated microwires with different geometrical aspect ratios, ρ = d metal / D total ( d metal -diameter of metallic nucleus, and D total -total diameter). The structure and magnetic properties are investigated in a wide range of temperatures and magnetic fields. The XRD analysis illustrates stable microstructure in the range of ρ from 0.25 to 0.60. The estimations of average grain size and crystalline phase content evidence a remarkable variation as the ρ -ratio sweeps from 0.25 to 0.60. Thus, the microwires with the lowest aspect ratio, i.e., ρ = 0.25, show the smallest average grain size and the highest crystalline phase content. This change in the microstructural properties correlates with dramatic changes in the magnetic properties. Hence, the sample with the lowest ρ -ratio exhibits an extremely high value of the coercivity, H c , compared to the value for the sample with the largest ρ -ratio (2989 Oe and 10 Oe, respectively, i.e., almost 300 times higher). In addition, a similar trend is observed for the spontaneous exchange bias phenomena, with an exchange bias field, H ex , of 120 Oe for the sample with ρ = 0.25 compared to a H ex = 12.5 Oe for the sample with ρ = 0.60. However, the thermomagnetic curves (field-cooled-FC and field-heating-FH) show similar magnetic behavior for all the samples. Meanwhile, FC and FH curves measured at low magnetic fields show negative values for ρ = 0.25, whereas positive values are found for the other samples. The obtained results illustrate the substantial effect of the internal stresses on microstructure and magnetic properties, which leads to magnetic hardening of samples with low aspect ratio.

Published

2024

277. Comparison of the Magnetic and Structural Properties of MnFePSi Microwires and MnFePSi Bulk Alloy.

Author

Salaheldeen M, Zhukova V, Rosero J, Salazar D, Ipatov M, and Zhukov A

Abstract

We provide comparative studies of the structural, morphological, microstructural, and magnetic properties of MnFePSi-glass-coated microwires (MnFePSi-GCMWs) and bulk MnFePSi at different temperatures and magnetic fields. The structure of MnFePSi GCMWs prepared by the Taylor-Ulitovsky method consists of the main Fe 2 P phase and secondary impurities phases of Mn 5 Si 3 and Fe 3 Si, as confirmed by XRD analysis. Additionally, a notable reduction in the average grain size from 24 µm for the bulk sample to 36 nm for the glass-coated microwire sample is observed. The analysis of magnetic properties of MnFePSi-glass-coated microwires shows different magnetic behavior as compared to the bulk MnFePSi. High coercivity (450 Oe) and remanence (0.32) are observed for MnFePSi-GCMWs compared to low coercivity and remanent magnetization observed for bulk MnFePSi alloy. In addition, large irreversibility at low temperatures is observed in the thermal dependence of magnetization of microwires. Meanwhile, the bulk sample shows regular ferromagnetic behavior, where the field cooling and field heating magnetic curves show a monotonic increase by decreasing the temperature. The notable separation between field cooling and field heating curves of MnFePSi-GCMWs is seen for the applied field at 1 kOe. Also, the M/M 5K vs. T for MNFePSi-GCMWs shows a notable sensitivity at a low magnetic field compared to a very noisy magnetic signal for bulk alloy. The common features for both MnFePSi samples are high Curie temperatures above 400 K. From the experimental results, we can deduce the substantial effect of drawing and quenching involved in the preparation of glass-coated MnFePSi microwires in modification of the microstructure and magnetic properties as compared to the same bulk alloy. The provided studies prove the suitability of the Taylor-Ulitovsky method for the preparation of MnFePSi-glass-coated microwires.

Published

2024

278. Monitoring the Velocity of Domain Wall Motion in Magnetic Microwires.

Author

Chizhik A, Corte-Leon P, Zhukova V, Blanco JM, and Zhukov A

Abstract

An approach was proposed to control the displacement of domain walls in magnetic microwires, which are employed in magnetic sensors. The velocity of the domain wall can be altered by the interaction of two magnetic microwires of distinct types. Thorough investigations were conducted utilizing fluxmetric, Sixtus-Tonks, and magneto-optical techniques. The magneto-optical examinations revealed transformation in the surface structure of the domain wall and facilitated the determination of the mechanism of external influence on the movement of domain walls in magnetic microwires.

Published

2024