Your search keyword '"Spin valve"' showing total 669 results

1. Guanine-based spin valve with spin rectification effect for an artificial memory element

Author

Iacob, Nicusor, Chirila, Cristina, Sangaré, Mama, Kuncser, Andrei, Stanciu, Anda E., Socol, Marcela, Negrila, Catalin C., Botea, Mihaela, Locovei, Claudiu, Schinteie, Gabriel, Galca, Aurelian C., Stanculescu, Anca, Pintilie, Lucian, Kuncser, Victor, and Borca, Bogdana

Published

2025

2. Gate-controllable two-dimensional transition metal dichalcogenides for spintronic memory

Author

Cheng, Shih-Hung, Kuo, Ting-I, Hsieh, Er-Feng, and Hsueh, Wen-Jeng

Published

2025

3. Enhancement of spin valve GMR sensor’s sensitivity with [Ta/NiFe][formula omitted] on-chip magnetic flux concentrator

Author

C.T., Gopika, K.P., Prajisha, Kaul, Apoorva, Borole, Umesh P., Khan, Jakeer, Behera, Bhagaban, and Chowdhury, P.

Published

2025

4. Increased Curie temperature and magnetoresistive response by modifying Fe/Mo ratio in Sr[formula omitted]FeMoO[formula omitted] thin films

Author

Naushahi, Naman A., Angervo, I., Saloaro, M., Schulman, A., Huhtinen, H., and Paturi, P.

Published

2022

5. Density of States in the Heterostructure Ferromagnetic Insulator-Superconductor-Ferromagnetic Insulator.

Author

Seleznev, D. V., Seidov, S. S., Pugach, N. G., Bezymiannykh, D. G., Mukhin, S. I., and L'vov, B. G.

Abstract

We consider a spin valve composed of a superconducting film (S) between two ferromagnetic insulators (FI) on two sides. In the dirty limit, the superconductor is described by Usadel equations. Appropriate boundary conditions were chosen for two S-FI interfaces, which are described via the interface parameter spin mixing angle. By numerically solving the Usadel equations, the density of states (DOS) at different spin mixing angles was obtained. It was shown previously that the critical temperature of such an FI-S-FI structure depends on the mutual alignment of the FI layers’ magnetization. We follow the evolution of DOS at the change of misalignment of ferromagnets magnetization and probe the zero bias peak creation. The DOS characteristic features may give fruitful information about triplet superconducting components creation and interplay inside the S layer. [ABSTRACT FROM AUTHOR]

Published

2025

6. Thermal and Spin-Orbital Effects under the Action of Current on Spin Valves Containing β-Ta and NiFeCr Alloy Layers.

Author

Naumova, L. I., Zavornitsyn, R. S., Milyaev, M. A., Germizina, A. A., Maksimova, I. K., Chernyshova, T. A., Pavlova, A. Yu., Proglyado, V. V., and Ustinov, V. V.

Abstract

For microobjects based on spin valves, changes in the magnetic state are observed under the action of short-term direct current. It has been shown that the magnetic moment of the free layer rotates when a certain current density is attained. The rotation angle grows with increasing current density. The magnetic moment rotates predominantly due to the thermal effect of current. Rotation angle changes caused by spin accumulation in Ta or NiFeCr layers and the transfer of the spin-orbit torque of electrons to the magnetic moment of the free layer have been revealed. [ABSTRACT FROM AUTHOR]

Published

2024

7. Structural Chirality and Electronic Chirality in Quantum Materials.

Author

Yan, Binghai

Abstract

In chemistry and biochemistry, chirality represents the structural asymmetry characterized by nonsuperimposable mirror images for a material such as DNA. In physics, however, chirality commonly refers to the spin–momentum locking of a particle or quasiparticle in the momentum space. While seemingly disconnected, structural chirality in molecules and crystals can drive electronic chirality through orbital–momentum locking; that is, chirality can be transferred from the atomic geometry to electronic orbitals. Electronic chirality provides an insightful understanding of chirality-induced spin selectivity, in which electrons exhibit salient spin polarization after going through a chiral material, and electrical magnetochiral anisotropy, which is characterized by diode-like transport. It further gives rise to new phenomena, such as anomalous circularly polarized light emission, in which the light handedness relies on the emission direction. These chirality-driven effects will generate broad impacts for fundamental science and technology applications in spintronics, optoelectronics, and biochemistry. [ABSTRACT FROM AUTHOR]

Published

2024

8. ADVANCEMENTS AND APPLICATIONS IN SEMICONDUCTOR SPINTRONICS: HARNESSING ELECTRON SPIN FOR NEXT-GENERATION DEVICES

Author

Kanaan Mohammad Musa

Subjects

Spintronics, MRAM, Spin LED, MTJ, Spin Valve, Electron Spin, Industrial engineering. Management engineering, T55.4-60.8

Abstract

Today’s semiconductor devices use the charges of electrons and holes for tasks like light emission and signal processing. Semiconductor spintronics, a newer field, aims to exploit the spin of charge carriers to advance technologies like magnetic lasers, sensors, and transistors. Spintronics could enable the creation of memory, sensing, and logic devices with capabilities that charge-based devices can't match. This work explores the progress made with spintronic materials and devices, their current uses, and what the future might hold. A key feature of emerging spintronic logic devices is their ability to generate highly spin-polarized currents in two- and three-terminal tunnel junctions, which can lead to devices that consume much less power than traditional charge-based ones. Recent advancements in material engineering give hope for the rapid development and deployment of these new spintronic technologies.

Published

2024

9. Superconducting properties of a thin-film heterostructure Fe1/Fe2/Pb on a piezoelectric substrate.

Author

Kamashev, A. A., Validov, A. A., Garif'yanov, N. N., Bolshakov, S. A., Garifullin, I. A., and Mamin, R. F.

Subjects

*SUPERCONDUCTING transition temperature, *SPIN valves, *MAGNETIC fields, *ELECTRIC fields, *SUPERCONDUCTIVITY, *SUPERCONDUCTING films

Abstract

The properties of a superconducting spin valve based on Fe1/Fe2/Pb prepared on a PMN-PT piezoelectric substrate ([Pb(Mg1/3Nb2/3)O3]0.7-[PbTiO3]0.3) in external magnetic and electric fields were studied. A shift in superconducting transition temperature more than 200 mK was observed when the mutual direction of the magnetizations of the ferromagnetic layers changed from antiparallel to perpendicular orientations in an external magnetic field. The possibility of realizing the full effect of a superconducting spin valve was demonstrated. It was established that the shift in superconducting transition temperature increased with an increase in the value of the applied electric field to the PMN-PT piezoelectric substrate. [ABSTRACT FROM AUTHOR]

Published

2024

10. ADVANCEMENTS AND APPLICATIONS IN SEMICONDUCTOR SPINTRONICS: HARNESSING ELECTRON SPIN FOR NEXT-GENERATION DEVICES.

Author

Musa, Kanaan Mohammad

Subjects

SPINTRONICS, SEMICONDUCTOR devices, MAGNETIC sensors, ELECTRON spin, SEMICONDUCTORS

Abstract

Today’s semiconductor devices use the charges of electrons and holes for tasks like light emission and signal processing. Semiconductor spintronics, a newer field, aims to exploit the spin of charge carriers to advance technologies like magnetic lasers, sensors, and transistors. Spintronics could enable the creation of memory, sensing, and logic devices with capabilities that charge-based devices can't match. This work explores the progress made with spintronic materials and devices, their current uses, and what the future might hold. A key feature of emerging spintronic logic devices is their ability to generate highly spin-polarized currents in two- and three-terminal tunnel junctions, which can lead to devices that consume much less power than traditional charge-based ones. Recent advancements in material engineering give hope for the rapid development and deployment of these new spintronic technologies. [ABSTRACT FROM AUTHOR]

Published

2024

11. Electromagnetic field detectors based on spintronics devices

Author

R.L. Politanskyi, P.M. Shpatar, M.V. Vistak, I.T. Kogut, I.S. Diskovskyi, and Yu.A. Rudyak

Subjects

electromagnetic field sensor, ferromagnetic resonance, spin current generation, spin valve, Physics, QC1-999

Abstract

The paper proposes a model of an electromagnetic radiation sensor that uses the precession of the magnetization vector in a ferromagnet (ferromagnetic resonance) as a result of absorbing the energy of an incident electromagnetic wave, the generation of a spin current as a result of this precession, the generation of a spin-polarized current as a result of the passage of a spin current in a non-magnetic metal, and a change in the direction of magnetization of a ferromagnetic layer with a low coercive force (free layer) due to the passage of a spin-polarized current. Then the radiation will be detected by its effect on the electrical resistance of the entire structure, which depends on the mutual directions (parallel or antiparallel) of magnetization of the free and fixed (with a large coercive force) ferromagnetic layers (phenomenon of giant magnetic resistance). The dependence of the spin-polarized current in the device on the frequency and amplitude of the incident electromagnetic wave with linear polarization was calculated. A method of calculating the range of amplitude and frequency values of radiation that can be detected by the sensor has been developed. The parameters of this model are the detection time and the number of spin gates in one sensor. Calculations are given for a ferromagnetic layer made of permalloy and for spin valves with four different critical current values that determine the process of remagnetization of the free layer: 20, 50, 100, and 200 microamps.

Published

2023

12. A Spin Valve-Based Rhombus-Shaped Micro-Object Implementing a Full Wheatstone Bridge.

Author

Milyaev, Mikhail, Naumova, Larisa, Germizina, Anastasiya, Chernyshova, Tatyana, Pavlova, Anastasia, Krinitsina, Tatiana, Proglyado, Vyacheslav, and Ustinov, Vladimir

Subjects

*EXCHANGE bias, *SPIN valves, *WHEATSTONE bridge, *MAGNETIC hysteresis, *COPPER, *LABOR theory of value

Abstract

Spin valves with a synthetic antiferromagnet were fabricated via magnetron sputtering. It was shown that the fabricated spin valve layers had a perfect microstructure and smooth interfaces, and therefore, an RKKY interaction dominated in the coupling of the ferromagnetic layers separated by a copper spacer. Rhombus-shaped micro-objects were fabricated from a single spin valve film. The thermomagnetic treatment procedure was found to form unidirectional anisotropy in the micro-object such that the values of the exchange bias fields in the rhombus' nonparallel sides were opposite in sign. For the CoFeNi/Ru/CoFeNi synthetic antiferromagnet, we determined the differences between the ferromagnetic layer thicknesses at which the thermomagnetic treatment formed the same exchange bias all over each rhombus' side. We also fabricated a sensor element in which each side of the rhombus was the shoulder of a Wheatstone bridge. After the thermomagnetic treatment procedure, each shoulder worked as an active magnetosensitive element, enabling the device to operate as a full Wheatstone bridge. The sensor output exhibited a step shape, high sensitivity to field changes, and significant magnetic hysteresis. Such characteristics are suitable for switching devices. [ABSTRACT FROM AUTHOR]

Published

2024

13. Recent innovations in 2D magnetic materials and their potential applications in the modern era.

Author

Elahi, Ehsan, Khan, Muhammad Asghar, Suleman, Muhammad, Dahshan, A., Rehman, Shania, Waseem Khalil, H.M., Rehman, Malik Abdul, Hassan, Ahmed M, Koyyada, Ganesh, Kim, Jae Hong, and Khan, Muhammad Farooq

Subjects

*MAGNETIC materials, *FIELD-effect transistors, *MAGNETIC tunnelling, *SPIN valves, *SPIN-orbit interactions

Abstract

[Display omitted] In recent years, enormous efforts have been made to identify and manipulate the exotic electrical and magnetic properties at a two-dimensional (2D) limit of various exciting materials. The spin–orbit coupling (SOC) in 2D van der Waals (vdW) heterostructures opens a fascinating and versatile platform to implement the intriguing quantum-engineered spintronic devices for practical applications. This review comprehensively outlines the modern-era progress of investigating the inherent magnetism of atomically thin 2D materials. Firstly, in this review, the most recent developments of synthesis, characterizations, functionalities, and spin textures in 2D magnetic materials are summarized in detail. Secondly, we conferred the well-known phenomena related to the proximity effect, spin–orbit torque (SOT), spin valve magnetic tunnel junction (MTJ), spin field effect transistor (FET) and magneto memristive-based applications. In addition, we also explored the possible interplay between 2D magnetic materials and associated band topology for spin caloritronics. Finally, we provided our perspective on the recent and upcoming challenges and goals of this promising research area, which leads the 2D magnetic materials to the modern era of energy-efficient quantum computing. [ABSTRACT FROM AUTHOR]

Published

2024

14. Spin diode and spin valve based on an interacting quantum dot coupled with nonmagnetic electrodes.

Author

Bo, Rui, Zhang, Zhengzhong, Tang, Yi, Guo, Yun, and Liu, Hao

Abstract

How to control the charge and spin in nanodevices is an important topic in spintronics. In this letter, we theoretically propose a spin diode and spin valve (SV) device controlled by all-electrical means, which is composed of a quantum dot (QD) coupled to a pair of nonmagnetic electrodes. When both electric charge bias and spin bias exist within the device, the I – V curves of this device exhibit an asymmetric distribution, and this asymmetry can be manipulated by the gate voltage. More interestingly, if we apply an external magnetic field on the QD, we can observe significant high- and low-resistance state switching with respect to the magnetic field, which can function as a SV device. This device scheme can be compatible with current technologies and has potential applications in spintronics or quantum processing. [ABSTRACT FROM AUTHOR]

Published

2023

15. Tunnel Josephson Junction with Spin–Orbit/Ferromagnetic Valve.

Author

Neilo, Alexey, Bakurskiy, Sergey, Klenov, Nikolay, Soloviev, Igor, and Kupriyanov, Mikhail

Subjects

*JOSEPHSON junctions, *SPIN valves, *THIN films, *VALVES, *SUPERCONDUCTIVITY, *SPACE-based radar

Abstract

We have theoretically studied the transport properties of the SIsN S O F structure consisting of thick (S) and thin (s) films of superconductor, an insulator layer (I), a thin film of normal metal with spin–orbit interaction (SOI) (N S O ), and a monodomain ferromagnetic layer (F). The interplay between superconductivity, ferromagnetism, and spin–orbit interaction allows the critical current of this Josephson junction to be smoothly varied over a wide range by rotating the magnetization direction in the single F-layer. We have studied the amplitude of the spin valve effect and found the optimal ranges of parameters. [ABSTRACT FROM AUTHOR]

Published

2023

16. Investigation of the influence of the properties of the piezoelectric substrate PMN-PT on the superconducting spin valve Fe/Al/Co/Pb.

Author

Kamashev, A. A., Validov, A. A., Garif'yanov, N. N., Bolshakov, S. A., Garifullin, I. A., and Mamin, R. F.

Subjects

*SPIN valves, *SUPERCONDUCTING transition temperature, *SUPERCONDUCTING transitions, *ELECTRIC fields, *MAGNETIC fields

Abstract

We have studied the influence of the piezoelectric properties of the PMN-PT substrate ([Pb(Mg1/3Nb2/3)O3]1-x – [PbTiO3]x where x = 0.29 − 0.31) on the properties of the superconducting spin valve Fe/Al/Co/Pb exposed to electric and magnetic fields. According to the research results, with an increase in the applied electric field to the PMN-PT substrate, it is possible to register an increase in the shift of the superconducting transition temperature of the superconducting spin valve Fe/Al/Co/Pb. The maximum shift was 36 mK when an electric field of 1 kV/cm was applied, which was half of the superconducting transition width. The shift of the superconducting transition temperature equal to 255 mK in a magnetic field was recorded, and thus the possibility of a full superconducting spin valve effect was shown. [ABSTRACT FROM AUTHOR]

Published

2023

17. Gate‐tunable spin valve effect in Fe3GeTe2‐based van der Waals heterostructures.

Author

Zhou, Ling, Huang, Junwei, Tang, Ming, Qiu, Caiyu, Qin, Feng, Zhang, Caorong, Li, Zeya, Wu, Di, and Yuan, Hongtao

Subjects

SPIN valves, MAGNETIC tunnelling, MAGNETIC properties, MAGNETIC fields, HETEROSTRUCTURES, SUPERCONDUCTING magnets, QUANTUM tunneling

Abstract

Magnetic tunnel junctions (MTJs), a prominent type of spintronic device based on the spin valve effect, have facilitated the development of numerous spintronic applications. The technical appeal for the next‐generation MTJ devices has been proposed in two directions: improving device performance by utilizing advanced two‐dimensional (2D) ferromagnetic materials or extending device functionalities by exploring the gate‐tunable magnetic properties of ferromagnets. Based on the recent development of 2D magnets with the ease of external stimuli, such as electric field, due to their reduced dimensions, reliable prospects for gate‐tunable MTJ devices can be achieved, shedding light on the great potential of next‐generation MTJs with multiple functionalities for various application environments. While the electrical gate‐tunable MTJ device is highly desirable for practical spintronic devices, it has not yet been demonstrated. Here, we demonstrate the experimental realization of a spin valve device by combining a vertical Fe3GeTe2/h‐BN/Fe3GeTe2 MTJ with an electrolyte gate. The magnetoresistance ratio (MR ratio) of 36% for the intrinsic MTJ confirms the good performance of the device. By electrolyte gating, the tunneling MR ratio of Fe3GeTe2/h‐BN/Fe3GeTe2 MTJ can be elevated 2.5 times, from 26% to 65%. Importantly, the magnetic fields at which the magnetoresistance switches for the MTJ can be modulated by electrical gating, providing a promising method to control the magnetization configuration of the MTJ. Our work demonstrates a gate‐tunable MTJ device toward the possibility for gate‐controlled spintronic devices, paving the way for performing 2D magnetism manipulations and exploring innovative spintronic applications. [ABSTRACT FROM AUTHOR]

Published

2023

18. The Magnetoelastic Properties of Spin Valves Containing CoFe/Dy Layers.

Author

Naumova, L. I., Zakharov, A. A., Milyaev, M. A., Bebenin, N. G., Zavornitsyn, R. S., Maksimova, I. K., Proglyado, V. V., and Ustinov, V. V.

Subjects

SPIN valves, POLYIMIDE films, DYSPROSIUM, MAGNETORESISTANCE

Abstract

Spin valves containing a Dy layer have been formed on an elastic polyimide film by magnetron sputtering. The field dependences of the magnetoresistance of samples subjected to different tensile deformations have been measured. The character of the variations of the magnetoresistive properties of a spin valve subjected to tensile deformation is shown to depend on the thickness of the dysprosium layer. In particular, the thickness of the dysprosium layer affects the maximum relative elongation at which the magnetoresistance of spin valves remains unchanged. [ABSTRACT FROM AUTHOR]

Published

2023

19. Gate‐tunable spin valve effect in Fe3GeTe2‐based van der Waals heterostructures

Author

Ling Zhou, Junwei Huang, Ming Tang, Caiyu Qiu, Feng Qin, Caorong Zhang, Zeya Li, Di Wu, and Hongtao Yuan

Subjects

Fe3GeTe2, magnetic tunnel junction, magnetoresistance, spin valve, van der Waals heterostructure, Materials of engineering and construction. Mechanics of materials, TA401-492, Information technology, T58.5-58.64

Abstract

Abstract Magnetic tunnel junctions (MTJs), a prominent type of spintronic device based on the spin valve effect, have facilitated the development of numerous spintronic applications. The technical appeal for the next‐generation MTJ devices has been proposed in two directions: improving device performance by utilizing advanced two‐dimensional (2D) ferromagnetic materials or extending device functionalities by exploring the gate‐tunable magnetic properties of ferromagnets. Based on the recent development of 2D magnets with the ease of external stimuli, such as electric field, due to their reduced dimensions, reliable prospects for gate‐tunable MTJ devices can be achieved, shedding light on the great potential of next‐generation MTJs with multiple functionalities for various application environments. While the electrical gate‐tunable MTJ device is highly desirable for practical spintronic devices, it has not yet been demonstrated. Here, we demonstrate the experimental realization of a spin valve device by combining a vertical Fe3GeTe2/h‐BN/Fe3GeTe2 MTJ with an electrolyte gate. The magnetoresistance ratio (MR ratio) of 36% for the intrinsic MTJ confirms the good performance of the device. By electrolyte gating, the tunneling MR ratio of Fe3GeTe2/h‐BN/Fe3GeTe2 MTJ can be elevated 2.5 times, from 26% to 65%. Importantly, the magnetic fields at which the magnetoresistance switches for the MTJ can be modulated by electrical gating, providing a promising method to control the magnetization configuration of the MTJ. Our work demonstrates a gate‐tunable MTJ device toward the possibility for gate‐controlled spintronic devices, paving the way for performing 2D magnetism manipulations and exploring innovative spintronic applications.

Published

2023

20. SINGLE MOLECULE MAGNETS

Author

Eufemio Moreno-Pineda

Subjects

Quantum sensors, quantum simulations, quantum computation, spin transistor, spin valve, quantum bit, Mathematics, QA1-939, Physics, QC1-999

Abstract

The utilisation of quantum properties can largely impact how technological devices work. Up to date, the acquired knowledge of the quantum nature of several systems inspired the proposal of several novel technologies such as quantum sensing, quantum simulation and quantum computing. Single Molecule Magnets (SMMs) represent a class of quantum objects with promising properties to be exploited in quantum technologies. As of today, SMMs have been shown to possess bewildering quantum effects such as Quantum Tunnelling of the Magnetisation (QTM), quantisation of the energy manifold, coherence, spin parity effects and entanglement, among others. Furthermore, they have been successfully integrated into hybrid single-molecule spintronic devices, such as spin transistors and spin valves, hence, propitiating extensive investigation of technological applications. In this Review Article, some key quantum aspects, which make SMMs promising systems for technological proposals, are revised. Moreover, single-molecule devices, in which SMMs have been integrated in hybrid devices, as well as the technological applications such as quantum sensing, quantum simulation and quantum computing are described.

Published

2023

21. SINGLE MOLECULE MAGNETS

Author

Concepción Molina-Jirón, Eufemio Moreno-Pineda, Lester Batista, Juan A. Jaén, and Wolfgang Wernsdorfer

Subjects

Quantum sensors, quantum simulations, quantum computation, spin transistor, spin valve, quantum bit, Mathematics, QA1-939, Physics, QC1-999

Abstract

The utilisation of quantum properties can largely impact how technological devices work. Up to date, the acquired knowledge of the quantum nature of several systems inspired the proposal of several novel technologies such as quantum sensing, quantum simulation and quantum computing. Single Molecule Magnets (SMMs) represent a class of quantum objects with promising properties to be exploited in quantum technologies. As of today, SMMs have been shown to possess bewildering quantum effects such as Quantum Tunnelling of the Magnetisation (QTM), quantisation of the energy manifold, coherence, spin parity effects and entanglement, among others. Furthermore, they have been successfully integrated into hybrid single-molecule spintronic devices, such as spin transistors and spin valves, hence, propitiating extensive investigation of technological applications. In this Review Article, some key quantum aspects, which make SMMs promising systems for technological proposals, are revised. Moreover, single-molecule devices, in which SMMs have been integrated in hybrid devices, as well as the technological applications such as quantum sensing, quantum simulation and quantum computing are described.

Published

2023

22. The Magnetotransport Properties of Spin Valves Based on Exchange-Coupled Dy Helimagnetic and Co90Fe10 Ferromagnetic Nanolayers.

Author

Naumova, L. I., Zavornitsyn, R. S., Milyaev, M. A., Makarova, M. V., Proglyado, V. V., Rusalina, A. S., and Ustinov, V. V.

Subjects

SPIN valves, MAGNETIC devices, NANOSTRUCTURED materials, DYSPROSIUM, MEASUREMENT of magnetic properties

Abstract

Spin valves with a CoFe/Dy/CoFe composition in the lower part of their structure have been manufactured by magnetron sputtering. The effect of prolonged storage and temperature on the structure and magnetotransport properties of spin valves has been studied. The change in the compensation temperature was used as an indicator of the intensity of diffusion processes in the exchange-coupled CoFe/Dy/CoFe structure. It has been revealed that diffusion induced changes in the magnetotransport properties become smaller with a decrease in the dysprosium layer thickness. It has been shown that the nanostructure still contains pure dysprosium, the atoms of which do not participate in the sperimagnetic ordering of the Dy–Co–Fe interface, even at a small nominal thickness (4 nm) of the dysprosium layer 3 months after sputtering. [ABSTRACT FROM AUTHOR]

Published

2022

23. Graphene-hybrid devices for spintronics

Author

Sambricio Garcia, Jose Luis and Grigorieva, Irina

Subjects

500, Spin transport, Spin valve, MTJ, 2D materials, Graphene, hBN

Abstract

This thesis explores the use of 2D materials (graphene and hBN) for spintronics. Interest on these materials in spintronics arose from theoretical predictions of high spin filtering in out-of-plane transport through graphene and hBN sandwiched by ferromagnets. Similarly, 5-layer graphene was forecast to be a perfect spin filter. In the case of in-plane spin transport, graphene was expected to be an excellent material due to its low spin-orbit coupling and low number of defects. Although there already exist experimental works that attempted to explore the aforementioned predictions, they have failed so far to comply with the expected results. Earlier experimental works in graphene and hBN out-of-plane spin transport achieved low spin filtering on the order of a few percent; while spin relaxation parameters in graphene for in-plane spin transport remained one or two orders of magnitude below the predicted values. In the case of vertical devices, the failure to meet the theoretical expectations was attributed to the oxidation of the ferromagnets and the lack of an epitaxial interface between the later and the graphene or hBN. Similarly, the exact mechanisms that lead to high spin relaxation for in-plane spin transport in graphene are not completely understood, in part due to the low-quality of the explored devices. In this thesis we analyze new architectures and procedures that allowed us to fabricate ultraclean and oxidation-free interfaces between ferromagnets and graphene or hBN. In these devices we encountered negative and reversible magnetoresistance, that could not be explained with the previous theoretical models. We propose a new model based on a thorough characterization of the devices and well-known properties of graphene that were not taken into account in the previous model. We also employed a novel type of contact to graphene (1D-contacts) and applied it for the first time to achieve spin-injection in graphene. The main advantage of this type of contact is the full encapsulation of graphene with hBN, which leads to high quality graphene spintronic devices.

Published

2017

24. Effect of Fe 3 O 4 Nanoparticles on CoFeB/Ta/CoFeB Spin-Valve Magnetoresistance Probed by Microwave Absorption.

Author

Koplak, Oksana, Allayarov, Ruslan, Kunitsyna, Ekaterina, and Morgunov, Roman

Subjects

*IRON oxide nanoparticles, *MAGNETIC dipoles, *DIPOLE interactions, *MICROWAVES

Abstract

The effect of nanoparticles (NPs) on microwave magnetoresistance in MgO/CoFeB(free)/Ta/CoFeB(fixed)/MgO)/Ta platform and the effect of individual NP on free CoFeB ferromagnetic layer magnetization have experimentally been revealed and analyzed. The area of the platform where magnetization is inverted under scattering field of NPs has been observed. Micromagnetic modeling of dipole magnetic interaction confirms the existence of such areas in “NP-platform” system. The increase in critical field of the platform and the change of resistance under scattering field on NPs have experimentally been revealed. [ABSTRACT FROM AUTHOR]

Published

2022

25. Molecular dynamics modeling of the influence forming process parameters on the structure and morphology of a superconducting spin valve

Author

Alexander Vakhrushev, Aleksey Fedotov, Vladimir Boian, Roman Morari, and Anatolie Sidorenko

Subjects

hybrid nanostructure, mathematical modeling, modified embedded-atom method, molecular dynamics, spintronics, spin valve, vacuum deposition, Technology, Chemical technology, TP1-1185, Science, Physics, QC1-999

Abstract

This work is a study of the formation processes and the effect of related process parameters of multilayer nanosystems and devices for spintronics. The model system is a superconducting spin valve, which is a multilayer structure consisting of ferromagnetic cobalt nanolayers separated by niobium superconductor nanolayers. The aim was to study the influence of the main technological parameters including temperature, concentration and spatial distribution of deposited atoms over the nanosystem surface on the atomic structure and morphology of the nanosystem. The studies were carried out using the molecular dynamics method using the many-particle potential of the modified embedded-atom method. In the calculation process the temperature was controlled using the Nose–Hoover thermostat. The simulation of the atomic nanolayer formation was performed by alternating the directional deposition of different composition layers under high vacuum and stationary temperature conditions. The structure and thickness of the formed nanolayers and the distribution of elements at their interfaces were studied. The alternating layers of the formed nanosystem and their interfaces are shown to have significantly different atomic structures depending on the main parameters of the deposition process.

Published

2020

26. Bottom-up Design of Magnetic and Magnetoresistive Materials Using Colloidal Nanoparticles

Author

Zhou, Benjamin Hsiaowei

Subjects

Materials Science, Nanoscience, Chemistry, Colloidal Nanoparticles, Composite Materials, Magnetoresistance, Spin Valve, Superferromagnetism

Abstract

Colloidal nanoparticles are an exciting class of materials for their ability to act as tunable building blocks for larger scale materials. The application of nanotechnology to magnetic materials depends on the controlled synthesis of uniform nanoparticles with targeted magnetization and magnetic anisotropy. The work presented in this dissertation has two focuses: one, the development of synthetic techniques which allow for the consistent production of uniform nanoparticles and of novel heterostructured nanoparticles with emergent magnetism, and two, the application of these nanoparticles into bulk magnetic and magnetoresistive assemblies. A common issue which plagues the study of nanoparticles is the variability of synthesis from written protocol to laboratory practice or even from batch to batch. A set of techniques are detailed which have been developed to ensure consistent recreation of reaction conditions which allow for separate LaMer ‘burst’ nucleation and growth regimes during synthesis. High-quality, single-phase nanoparticles synthesized using the preceding techniques were further used as seeds in the synthesis of novel heterostructured nanoparticles exhibiting enhanced exchange bias.Collective magnetism was studied in assemblies of ferrimagnetic Fe3O4 and antiferromagnetic CoO nanoparticles. In typical samples consisting only of permanent magnetic nanoparticles, dipolar interactions between the nanoparticles frustrate the orientation of their magnetic moments, often producing a superspin glass state. Conversely, antiferromagnetic nanoparticles, in their dipolar interactions with ferro- or ferrimagnetic nanoparticles, induce a uniaxial magnetic anisotropy and create a superferromagnetic state in the collective magnetism of the nanoparticle assemblySynthetic control over nanoparticle morphology was exploited to engineer nanoparticles for the assembly of granular magnetoresistance devices. Magnetoresistance measurements on a series of pellets of differently sized CoFe2O4 nanoparticles revealed a size threshold beyond which magnetoresistance was greatly diminished. Additionally, the magnetoresistance of CoFe2O4 was found to be superior to that of Fe3O4 despite the latter’s popularity in magnetoresistance research. Magnetoresistance measurements were also performed on mixed nanoparticle films cast from nanoparticle inks. Tuning of the CoFe2O4 to Fe3O4 ratio in the films successfully produced pseudo spin valve magnetoresistance, improving both the magnitude and responsivity of the films’ magnetoresistance.

Published

2022

27. Flexible Spin Valves: Interlayer Interaction and Deformation Sensitivity.

Author

Naumova, L. I., Chernyshova, T. A., Zavornitsyn, R. S., Milyaev, M. A., Maksimova, I. K., Proglyado, V. V., Zakharov, A. A., and Ustinov, V. V.

Abstract

Exchange-coupled spin valves based on ferromagnetic alloys CoFeNi and antiferromagnetic alloy FeMn are obtained on flexible polyimide substrates by magnetron sputtering. The magnetoresistive properties of films and microstrips of spin valves are measured at various degrees of bending deformation of the sample. The behavior of the dependence of the deformation sensitivity of the spin valve on the interaction between the magnetic layers and on the arrangement of the anisotropy axes with respect to the deformation vector is characterized. It is found that the deformation sensitivity decreases with an increase in the interval between the fields of magnetization reversal of the free and fixed layers in the spin valve. [ABSTRACT FROM AUTHOR]

Published

2021

28. Spin Valves as a Tool for Studying Helicoidal Magnetism.

Author

Ustinov, V. V., Milyaev, M. A., Naumova, L. I., Zavornitsyn, R. S., Krinitsina, T. P., and Proglyado, V. V.

Abstract

Exchange-biased nanostructures of the "spin valve" type, which include an additional layer of the rare-earth metal dysprosium, are made by magnetron sputtering. Temperature variations in the magnetotransport properties of the spin valves are used as an indicator of change in the magnetic state of the dysprosium nanolayer. Information on the formation of unidirectional magnetic anisotropy at the CoFe/Dy interface upon the transition through Néel temperature of dysprosium is obtained. It is shown that the antiferromagnetic phase in the polycrystalline dysprosium layer has noncollinear magnetic ordering. The temperature dependence of the angle between the directions of the magnetic moments at the dysprosium-layer boundaries is determined. The change in this angle observed in the entire temperature region of the existence of helicoidal ordering in dysprosium reflects the change in the period of the magnetic helicoid in dysprosium with temperature. Thus, a new method for studying chiral magnetics is proposed, in which the indicator of the helicoidal magnetic state is a spin valve possessing giant magnetoresistance, containing a layer of the helimagnet under investigation. [ABSTRACT FROM AUTHOR]

Published

2021

29. Movable-Type Transfer and Stacking of van der Waals Heterostructures for Spintronics

Author

Yuan Cao, Xinhe Wang, Xiaoyang Lin, Wei Yang, Chen Lv, Yuan Lu, Youguang Zhang, and Weisheng Zhao

Subjects

movable-type, PVA transfer, two-dimensional materials, spin valve, spintronics, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The key to achieving high-quality and practical van der Waals heterostructure devices made from various two-dimensional (2D) materials lies in the efficient control over clean and flexible interfaces. Inspired by the “movable-type printing”, one of the four great inventions of ancient China, we demonstrate the “movable-type” transfer and stacking of 2D materials, which utilizes prefabricated polyvinyl alcohol (PVA) film to engineer the interfacial adhesion to 2D materials, and provides a flexible, efficient and batchable transfer scheme for 2D materials. The experiments also verify the “movable-type” transfer can preciously control the position and orientation of 2D materials, which meets the burgeoning requirements such as the preparation of twisted graphene and other heterostructures. Importantly, water-solubility of PVA film ensures an ideal interface of the materials without introducing contamination. We illustrate the superiority of this method with a WSe2 vertical spin valve device, whose performance verifies the applicability and advantages of such a method for spintronics. Our PVA-assisted “movable-type” transfer process may promote the development of high-performance 2D-material-based devices.

Published

2020

30. Giant magnetoresistance ratio in a current-perpendicular-to-plane spin valve based on an inverse Heusler alloy Ti2NiAl

Author

Yu Feng, Zhou Cui, Bo Wu, Jianwei Li, Hongkuan Yuan, and Hong Chen

Subjects

current-perpendicular-to-plane geometry, Heusler alloy, nonequilibrium Green’s function, spin transport, spintronics, spin valve, Technology, Chemical technology, TP1-1185, Science, Physics, QC1-999

Abstract

A Ti2NiAl inverse Heusler alloy based current-perpendicular-to-plane (CPP) spin valve (SV) with various kinds of atomic terminated interfaces has been designed to explore the potential application of Heusler alloys in spintronics devices. By performing first principles calculations combined with the nonequilibrium Green’s function, it is revealed that spin magnetic moments of interfacial atoms suffer a decrease, and the electronic structure shows that the TiNiB-terminated structure possesses the largest interface spin polarization of ≈55%. Our study on spin-transport properties indicates that the total transmission coefficient at the Fermi level mainly comes from the contribution from the spin up electrons, which are regarded as the majority of the spin electrons. When the two electrodes of the CPP-SV device are in parallel magnetization configuration, the interface containing Ti and Ni atoms possesses a higher spin up transmission coefficient than the interface containing Ti and Al atoms. The device with the TiNiB-terminated interface possesses the largest magnetoresistance ratio of 3.28 × 105, and it has great application potential in spintronics devices.

Published

2019

31. Periodic Co/Nb pseudo spin valve for cryogenic memory

Author

Nikolay Klenov, Yury Khaydukov, Sergey Bakurskiy, Roman Morari, Igor Soloviev, Vladimir Boian, Thomas Keller, Mikhail Kupriyanov, Anatoli Sidorenko, and Bernhard Keimer

Subjects

cryogenic computing, neutron scattering, spin valve, superconducting spintronics, Technology, Chemical technology, TP1-1185, Science, Physics, QC1-999

Abstract

We present a study of magnetic structures with controllable effective exchange energy for Josephson switches and memory applications. As a basis for a weak link we propose to use a periodic structure composed of ferromagnetic (F) layers spaced by thin superconductors (s). Our calculations based on the Usadel equations show that switching from parallel (P) to antiparallel (AP) alignment of neighboring F layers can lead to a significant enhancement of the critical current through the junction. To control the magnetic alignment we propose to use a periodic system whose unit cell is a pseudo spin valve of structure F1/s/F2/s where F1 and F2 are two magnetic layers having different coercive fields. In order to check the feasibility of controllable switching between AP and P states through the whole periodic structure, we prepared a superlattice [Co(1.5 nm)/Nb(8 nm)/Co(2.5 nm)/Nb(8 nm)]6 between two superconducting layers of Nb(25 nm). Neutron scattering and magnetometry data showed that parallel and antiparallel alignment can be controlled with a magnetic field of only several tens of Oersted.

Published

2019

32. Formation of Unidirectional Magnetic Anisotropy in a Spin Valve Containing a Dysprosium Layer.

Author

Naumova, L. I., Zavornitsyn, R. S., Milyaev, M. A., Makarova, M. V., Proglyado, V. V., and Ustinov, V. V.

Abstract

The dependence of the Neel temperature on the thickness of the dysprosium layer has been studied. It is shown that the temperature range within which the paramagnetic–antiferromagnetic phase transition takes place depends on the microstructure and thickness of the dysprosium layer. Spin valves based on a CoFe alloy with dysprosium as an antiferromagnetic layer are manufactured via magnetron sputtering. It is shown that unidirectional anisotropy forms in the CoFe/Dy interface. The direction of the exchange bias field depends on the direction of the magnetic moment of the CoFe layer in the formation of exchange coupling. [ABSTRACT FROM AUTHOR]

Published

2021

33. Nanoscale investigation of superconductivity and magnetism using neutrons and muons

Author

Ray, Soumya Jyoti and Lee, Stephen

Subjects

621.3, Superconductivity, Magnetism, Nanomagnetism, Interplay of superconductivity and magnetism, Proximity effect, Inverse proximity effect, Spin valve, Spin triplet superconductivity, Polarised neutron reflectivity, Muon spin rotation, Magneto-transport measurements, SQUID, BiSCCO, Strontium ruthanate, Perpendicular magnetic anisotropy, Vortex magnetic phase diagram

Abstract

The work presented in this thesis was broadly focussed on the investigation of the magnetic behaviour of different superconducting materials in the form of bulk (singe crystals and pellets) and thin films (nanomagnetic devices like superconducting spin valves etc). Neutrons and muons were extensively used to probe the structural and magnetic behaviour of these systems at the nanoscale along with bulk characterisation techniques like high-sensitive magnetic property measurements, scanning probe microscopy and magneto-transport measurements etc. The nanoscale interplay of Superconductivity and Ferromagnetism was studied in the thin film structures using a combination of Polarised Neutron Reflectivity (PNR) and Low Energy Muon Spin Rotation (LE-µSR) techniques while bulk Muon Spin Rotation (µSR) technique was used for microscopic magnetic investigation in the bulk materials. In the Fe/Pb heterostructure, evidence of the Proximity Effect was observed in the form of an enhancement of the superconducting penetration depth (λs) with an increase in the ferromagnetic layer thickness (dF) in both the bilayered and the trilayered structures. The existence of an Inverted Magnetic Region was also detected at the Ferromagnet-Superconductor (F/S) interface in the normal state possibly originating from the induced spin polarisation within the Pb layer in the presence of the neighbouring Fe layer(s). The spatial size (height and width) of the Inverted Magnetic Region did not change much while cooling the sample below the superconducting transition temperature(Tc)and it also stayed unaffected by an increase in the Fe layer thickness and by a change of the applied magnetic field. In the superconducting spin valve structure containing Permalloy (Py) as ferromagnetic layer and Nb as the superconducting layer, LE-µSR measurements revealed the evidence of the decay of magnetic flux density (as a function of thickness) within the Nb layer symmetrically from the Py/Nb interfaces towards the centre of the Nb layer in the normal state. The thickness dependent magnetisation decay occurred over two characteristic length scales in the normal state that stayed of similar values in the superconducting state also. In the superconducting state, an additional contribution towards the magnetisation was found in the vicinity of the Py/Nb interfaces possibly originating from the spin polarisation of the singlet Cooper pairs in these areas. The nanoscale magnetic investigation on a highly engineered F/S/F structure (where each of the F blocks made of multiple Co/Pd layers with magnetic moments aligned perpendicular to the plane of these layers and neighbouring magnetic blocks separated by Ru layers giving rise to antiferromagnetic alignment) using LE-µSR showed an antisymmetric thickness dependent magnetic flux density profile with two characteristic length scales. In the superconducting state, the magnetic flux density profile got modified within the superconducting Nb₆₇Ti₃₃ layer near the F/S interfaces in a way similar to that of observed in the case of Py/Nb system, most likely because of the spin polarisation of the superconducting electron pairs. The vortex magnetic phase diagram of Bi₂Sr₂Ca₂Cu₃O10-δ was studied using the Muon Spin Rotation (µSR) technique to explore the effects of vortex lattice melting and rearrangements for vortex transitions and crossover as a function of magnetic field and temperatures. At low magnetic fields, the flux vortices undergo a first order melting transition from a vortex lattice to a vortex liquid state with increasing temperature while another transition also occurred with increasing field at fixed temperature to a vortex glass phase at the lowest temperatures. Evidence of a frozen liquid phase was found in the intermediate field region at low temperature in the form of a lagoon in the superconducting vortex state which is in agreement with earlier observations made in BiSCCO-2212. The magnetic behaviour of the unconventional superconductor Sr₂RuO₄ was investigated using µSR to find the evidence of normal state magnetism and the nature of the vortex state. In the normal state, a weak hysteretic magnetic signal was detected over a wide temperature and field range believed to be supporting the evidence of a chiral order parameter. The nature of the vortex lattice structure was obtained in different parts of the magnetic phase diagram and the evidence of magnetic field driven transition in the lattice structure was detected from a Triangular→Square structure while the vortex lattice stayed Triangular over the entire temperature region below Tc at low fields with a disappearance of pinning at higher temperatures.

Published

2012

34. The Magnetotransport Properties of Spin Valves Based on Exchange-Coupled Dy Helimagnetic and Co90Fe10 Ferromagnetic Nanolayers

Author

Naumova, L. I., Zavornitsyn, R. S., Milyaev, M. A., Makarova, M. V., Proglyado, V. V., Rusalina, A. S., and Ustinov, V. V.

Published

2022

35. Medium dynamic field range linear bipolar spin valve sensor through soft pinning the sensing layer.

Author

Gawade TC, Borole UP, Behera B, Ghosh SK, Bysakh S, Biswas A, Khan J, and Chowdhury P

Abstract

Magnetic sensor with spin valve-GMR technology with medium dynamic range is designed for a diversity of applications, including linear and rotary position measurements, proximity switches, and current sensors. For this, the sensing layer (SL) of the spin valve stack was modified by a soft pinning layer (SPL) through an exchange bias field created by an antiferromagnetic layer which has a lower blocking temperature than the one that is kept adjacent to the pinned layer. Numerical simulation was carried out to control the bias field by keeping a non-magnetic Ru spacer layer between the SPL and SL layers and the results were experimentally verified. The magnetic sensor was fabricated with linear operating field range of the order ±100 Oe having a sensitivity of the order of 0.1 m V V -1 Oe -1 near zero field. The thermal performance confirms that the device can be operated in the temperature range of -40 ∘ C to 125 ∘ C and it has a thermal coefficient of voltage around 15 µ V V -1∘ C -1 ., (© 2024 IOP Publishing Ltd.)

Published

2024

36. The Application of Organic Semiconductor Materials in Spintronics

Author

Yixiao Zhang, Lidan Guo, Xiangwei Zhu, and Xiangnan Sun

Subjects

organic spintronics, π-conjugated semiconductor, spin transport, multifunctional spintronic device, spin manipulation, spin valve, Chemistry, QD1-999

Abstract

π-Conjugated semiconductors, primarily composed of elements with low atomic number, are regarded as promising spin-transport materials due to the weak spin–orbit coupling interaction and hence long spin relaxation time. Moreover, a large number of additional functions of organic semiconductors (OSCs), such as the abundant photo-electric properties, flexibility, and tailorability, endow the organic spintronic devices more unique properties and functionalities. Particularly, the integration of the photo-electric functionality and excellent spin transport property of OSCs in a single spintronic device has even shown great potential for the realization of spin manipulation in OSCs. In this review, the application of OSCs in spintronic study will be succinctly discussed. As the most important and extensive application, the long-distance spin transport property of OSCs will be discussed first. Subsequently, several multifunctional spintronic devices based on OSCs will be summarized. After that, the organic-based magnets used for the electrodes of spintronic devices will be introduced. Finally, according to the latest progress, spin manipulation in OSCs via novel spintronic devices together with other prospects and challenges will be outlined.

Published

2020

37. Increasing the performance of a superconducting spin valve using a Heusler alloy

Author

Andrey A. Kamashev, Aidar A. Validov, Joachim Schumann, Vladislav Kataev, Bernd Büchner, Yakov V. Fominov, and Ilgiz A. Garifullin

Subjects

ferromagnet, proximity effect, spin valve, superconductor, Technology, Chemical technology, TP1-1185, Science, Physics, QC1-999

Abstract

We have studied superconducting properties of spin-valve thin-layer heterostructures CoOx/F1/Cu/F2/Cu/Pb in which the ferromagnetic F1 layer was made of Permalloy while for the F2 layer we have taken a specially prepared film of the Heusler alloy Co2Cr1−xFexAl with a small degree of spin polarization of the conduction band. The heterostructures demonstrate a significant superconducting spin-valve effect, i.e., a complete switching on and off of the superconducting current flowing through the system by manipulating the mutual orientations of the magnetization of the F1 and F2 layers. The magnitude of the effect is doubled in comparison with the previously studied analogous multilayers with the F2 layer made of the strong ferromagnet Fe. Theoretical analysis shows that a drastic enhancement of the switching effect is due to a smaller exchange field in the heterostructure coming from the Heusler film as compared to Fe. This enables to approach an almost ideal theoretical magnitude of the switching in the Heusler-based multilayer with a F2 layer thickness of ca. 1 nm.

Published

2018

38. Mobility of magnetic helicoid in holmium nano-layer.

Author

Zavornitsyn, R.S., Naumova, L.I., Milyaev, M.A., Makarova, M.V., Proglyado, V.V., Maksimova, I.K., and Ustinov, V.V.

Abstract

Spin valves with holmium layers and three-layer structures metal/Ho/metal were prepared by magnetron sputtering. A holmium layer in the spin valves is polycrystalline with weak axial <002> texture. The structural coherence length along the hexagonal c-axis is approximately 2/5 of the total thickness of the holmium layer. Field dependences of the spin valves magnetoresistance were measured at different temperatures. Correlation was revealed between magnetic state in holmium layer and the shape of magnetoresistive curve. Deviation of magnetic moments of the reference layer and the adjacent part of holmium from the applied magnetic field was investigated. The field induced mobility of the magnetic helicoid in holmium layers was revealed. Image 1 • Neel temperature of Ho layer depends on the thickness and microstructure perfection. • Antiferromagnetic Ho layer carries out exchange bias in the adjacent ferromagnetic. • Spin valve magnetoresistance correlates with the magnetic state in Ho layer. • Period of the magnetic helicoid in Ho layer varies with temperature. • The magnetic helicoid in Ho layer is rotated around c-axis by magnetic field. [ABSTRACT FROM AUTHOR]

Published

2020

39. Linearization of Patterned Pinning Spin Valve Devices for Low-Field Applications.

Author

Luong, Van Su

Subjects

SPIN valves, MAGNETRON sputtering, DC sputtering

Abstract

In spin valve sensors, the bias point caused by the interlayer coupling between the pinned layer and the free layer is a crucial issue encountered in the design process, which degrades the responsivity and the weak-field detection feature. In tackling this issue, we present the magnetic bias technique for efficient control of the bias point of the pinned spin valve (PSV). Specifically, the magnetic field that creates a shift of the bias point is generated by a coil being wrapped around the PSV devices. The PSV multilayer structure, Ta(5 nm)/NiFe(3 nm)/CoFe(4.5 nm)/Cu(1.5 nm)/CoFe(2.4 nm)/IrMn(10 nm)/Ta(5 nm), was fabricated using DC magnetron sputtering deposition. The PSV devices patterned by using a simple lift-off technique have a dimension of 1.5 µm × 200 µm. The bias magnetic field was tuned between ± 5 mT by changing an external DC current. Our experimental results indicate that the bias point can be efficiently controlled via a simple adjustment of the current in the bias coil. Consequently, the device responsivity was remarkably enhanced by a factor of 6.75, from 0.8 V/T to 5.4 V/T, leading to a decrease of the detectivity (field noise) from 366 nT/√Hz@1 Hz to 108 nT/√Hz@1 Hz. Additionally, the field noise was further suppressed by a factor of 5 from 363 nT/√Hz@1 Hz to 72 nT/√Hz@1 Hz by applying the AC-driven mode in the half-bridge PSV. The simplicity of our proposed technique makes it particularly pertinent to PSV sensor designs for low-field applications. [ABSTRACT FROM AUTHOR]

Published

2020

40. Use of a Spin-Flop State for the Creation of Spin-Valve Elements for a Full Wheatstone Bridge.

Author

Milyaev, M. A., Naumova, L. I., Zavornitsyn, R. S., Maksimova, I. K., Pavlova, A. Yu., Proglyado, V. V., and Ustinov, V. V.

Abstract

A method of universal thermomagnetic treatment forming a pairwise opposite exchange bias in spin valves, which are sensor elements of a Wheatstone bridge, has been developed. The method is based on the formation of two magnetic phases in a spin valve upon the transition of a synthetic antiferromagnet into a spin-flop state. Thermomagnetic treatment in a two-phase state leads to the formation of a pairwise mutually opposite exchange bias in different elements of a Wheatstone bridge. The direction of a formed exchange bias is governed by the uniaxial anisotropy of every element. [ABSTRACT FROM AUTHOR]

Published

2020

41. Accumulation of spin-polarized states of charge carriers and a spintronic battery.

Author

Pastur, L. А., Slavin, V. V., and Yanovsky, A. V.

Subjects

*CHARGE carriers, *SPIN valves, *ELECTRIC batteries, *ELECTRON tubes, *CONDUCTION electrons, *LEAD-acid batteries, *SUPERCAPACITORS

Abstract

Spin valves based on materials in which the spin-flip is suppressed by the spatial separation of charge carriers, while maintaining electric neutrality in the valve volume, are considered. The possibility of using these valves as electric batteries is discussed. Regulating the potential difference on the valve, one can expect the effects of incommensurability of the type of "devil's staircase" associated with the Coulomb interaction and redistribution of electrons occurring while the battery is charged and discharged. The effects of the emergence and vanishing of spontaneous spin polarization of conduction electrons with a change in the Fermi level in the valve are predicted. Such spin valves can also be used in implementing spintronic memory cells, supercapacitors, and similar devices. [ABSTRACT FROM AUTHOR]

Published

2020

42. Noncollinear Magnetic Order in a Dysprosium Layer and Magnetotransport Properties of a Spin Valve Containing the CoFe/Dy/CoFe Structure.

Author

Zavornitsyn, R. S., Naumova, L. I., Milyaev, M. A., Makarova, M. V., Krinitsina, T. P., Proglyado, V. V., and Ustinov, V. V.

Abstract

Spin valves comprising a synthetic antiferromagnet and a CoFe/Dy/CoFe structure in the pinned layer were prepared by magnetron sputtering. It is shown that the Dy layer is characterized by crystallites, the [0002] direction of which is perpendicular to the film plane; a part of nanostructure, in which the spin-dependent electron scattering occurs, is characterized by smooth interfaces. Variations of magnetotransport properties of the spin valve, which are due to the formation of antiferromagnetic order in the dysprosium layer, are observed. Peculiarities of noncollinear magnetic order of the Dy layer were found to depend on the direction of magnetic moments of adjacent layers and magnetic field strength when passing through the Néel temperature. [ABSTRACT FROM AUTHOR]

Published

2020

43. Boosting the Curie temperature of GaN monolayer through van der Waals heterostructures.

Author

Wu Q, Wang J, Zhi T, Zhuang Y, Tao Z, Shao P, Cai Q, Yang G, Xue J, Chen D, and Zhang R

Abstract

The pursuit of van der Waals (vdW) heterostructures with high Curie temperature and strong perpendicular magnetic anisotropy (PMA) is vital to the advancement of next generation spintronic devices. First-principles calculations are used to study the electronic structures and magnetic characteristics of GaN/VS 2 vdW heterostructure under biaxial strain and electrostatic doping. Our findings show that a ferromagnetic ground state with a remarkable Curie temperature (477 K), much above room temperature, exists in GaN/VS 2 vdW heterostructure and 100% spin polarization efficiency. Additionally, GaN/VS 2 vdW heterostructure still maintains PMA under biaxial strain, which is indispensable for high-density information storage. We further explore the electron, magnetic, and transport properties of VS 2 /GaN/VS 2 vdW sandwich heterostructure, where the magnetoresistivity can reach as high as 40%. Our research indicates that the heterostructure constructed by combining the ferromagnet VS 2 and the non-magnetic semiconductor GaN is a promising material for vdW spin valve devices at room temperature., (© 2024 IOP Publishing Ltd.)

Published

2024

44. Spin Valves in Microelectronics (A Review)

Author

Iusipova, Iu. A. and Popov, A. I.

Published

2021

45. Precession of Magnetization of a Spin-Valve Free Layer and Its Switching under the Effect of a Magnetic Field Perpendicular to the Anisotropy Axis.

Author

Iusipova, Iu. A.

Subjects

*MAGNETIC field effects, *SPIN valves, *MAGNETIC anisotropy, *MAGNETIZATION, *RANDOM access memory, *PERPENDICULAR magnetic anisotropy

Abstract

Modern microelectronic devices based on layered spin-valve structures have low power inputs, a high reliability, and a broad temperature range. Studying dynamic spin-valve modes and the possibilities of controlling these modes are of practical interest. In this work, the operating modes of a spin valve, which comprise the base for magnetoresistive random-access memory (MRAM), a binary stochastic neuron (p-bit), and various spin-transfer nanooscillators (STNOs) are considered. A mathematical model of the spin valve with longitudinal anisotropy placed into a magnetic field parallel to the anisotropy axis and perpendicular to the plane of layers is constructed. A set of equations that describe the dynamics of the magnetization vector of the free layer of the spin valve is derived. Quantitative analysis of the set of equations enables determination of the equilibrium positions of magnetization of the free layer for the spin-valve structure. The conditions for changing the type of singular points of the dynamic set of equations are found based on the bifurcation analysis of the set. Investigation into the dynamics of the magnetization vector of the free layer of a spin valve enables determination of its main operational modes as the component of the magnetoresistive random access memory, binary stochastic neuron, and spin-transfer nanooscillator, as well as the ranges of the current and magnetic field corresponding to these modes. The frequency and amplitude characteristics are calculated for spin-valve oscillators. The proposed structure with anisotropy located in a field perpendicular to the anisotropy axis is more preferable when compared to a structure with a field applied parallel to the anisotropy axis from the viewpoint of its application as the spin-transfer nanooscillator. [ABSTRACT FROM AUTHOR]

Published

2019

46. Spin detection using a ferromagnetic noncollinear spin valve.

Author

Hao, Runrun, Zhou, Tie, Zhong, Hai, Kang, Shishou, Liu, Guolei, Bai, Lihui, Han, Guangbing, Yu, Shuyun, and Yan, Shishen

Subjects

*SPIN valves, *MAGNETIC structure

Abstract

• The detected amplitude of spin current emitted by spin pumping depends on the NiFe magnetic states. • A spin valve-like behavior with reliable amplitude changes up to 110%. • Paving the road towards ultralow-dissipation spintronic devices based on pure spin current. Ferromagnetic noncollinear spin valve effect has been observed in a magnetic multilayer structure of IrMn/NiFe/Cu/Y 3 Fe 5 O 12 (YIG). In this structure, the detected amplitude of spin current emitted by spin pumping depends on the NiFe magnetic states (saturation or unsaturation). This yields a spin valve-like behavior with reliable amplitude changes up to 110% and the behavior may originate from the difference of spin absorption when the NiFe layer is magnetically saturated or not. Our results provide a ferromagnetic noncollinear spin valve, paving the road towards ultralow-dissipation spintronic devices based on pure spin current. [ABSTRACT FROM AUTHOR]

Published

2019

47. High-Sensitive Sensing Elements Based on Spin Valves with Antiferromagnetic Interlayer Coupling.

Author

Naumova, L. I., Milyaev, M. A., Zavornitsin, R. S., Pavlova, A. Yu., Maksimova, I. K., Krinitsina, T. P., Chernyshova, T. A., Proglyado, V. V., and Ustinov, V. V.

Abstract

Spin valves Ta/(Ni80Fe20)60Cr40/Co70Fe20Ni10/Cu/Co70Fe20Ni10/Ru/Co70Fe20Ni10/Fe50Mn50/Ta have been prepared by magnetron sputtering. It was found that the shift of low-field hysteresis loop with respect to H = 0 oscillates as the copper layer thickness changes. Structural studies showed the high perfection of the layer microstructure. Films of spin valves with the copper layer thickness corresponding to the second antiferromagnetic RKKI interaction maximum have been synthesized. They exhibit zero shift of low-field hysteresis loop and are characterized by high magnetoresistance effect. Sensing elements in the form of meanders prepared using the films demonstrate the almost anhysteretical field dependence of magnetoresistance and a magnetoresistive sensitivity of 0.5%/Oe. [ABSTRACT FROM AUTHOR]

Published

2019

48. Large-area GMR bio-sensors based on reverse nucleation switching mechanism.

Author

Su, Diqing, Wu, Kai, and Wang, Jian-Ping

Subjects

*BIOSENSORS, *NUCLEATION, *BIOMARKERS, *SPIN valves, *MAGNETIZATION reversal

Abstract

Highlights • The sensitivity of stripe-shaped GMR biosensors is limited. • Biological detection in large-area sensors is realized by the reverse nucleation sites under MNPs. • Large-area sensors exhibit better linearity 20 times higher sensitivity. Abstract In the past 20 years, several studies have been performed on the detection of biomarkers by the stripe-shaped spin valve sensors, whose sensitivity is limited by their small sensing area and large sensor resistance. In this paper, large-area spin valve sensors with lower aspect ratio are introduced. A reverse nucleation mechanism is proposed to demonstrate the different switching processes in large-area sensors. The simulation results further prove the involvement of reverse nucleation sites during the magnetization reversal. Large-area sensors also exhibit a linear response to the concentration of magnetic nanoparticles with a sensor signal more than 20 times larger than the stripe sensors. [ABSTRACT FROM AUTHOR]

Published

2019

49. Spintronics: A contemporary review of emerging electronics devices

Author

Vinod Kumar Joshi

Subjects

Spin valve, GMR, MTJ, FTJ, Spin-FET, Spin-MOSFET, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Spintronics is a new field of research exploiting the influence of electron spin on the electrical conduction (or current is spin dependent). The major problem is the realization and fabrication of spintronics based devices. To meet the objective scientific community is developing the novel kind of materials that relies on magnetism instead of flow of current through electron. This paper illustrates and reviews one of the emerging technologies known as spintronics by putting few low power computing techniques altogether based on spintronics to provide a basic and meaningful understanding to the reader. The challenges of spintronics devices that has to meet for the success of electronics future are summarized.

Published

2016

50. Strong Ferromagnetically-Coupled Spin Valve Sensor Devices for Droplet Magnetofluidics

Author

Gungun Lin, Denys Makarov, and Oliver G. Schmidt

Subjects

droplet microfluidics, spin valve, ferromagnetic coupling, high field sensing, ferrofluid, Chemical technology, TP1-1185

Abstract

We report a magnetofluidic device with integrated strong ferromagnetically-coupled and hysteresis-free spin valve sensors for dynamic monitoring of ferrofluid droplets in microfluidics. The strong ferromagnetic coupling between the free layer and the pinned layer of spin valve sensors is achieved by reducing the spacer thickness, while the hysteresis of the free layer is eliminated by the interplay between shape anisotropy and the strength of coupling. The increased ferromagnetic coupling field up to the remarkable 70 Oe, which is five-times larger than conventional solutions, brings key advantages for dynamic sensing, e.g., a larger biasing field giving rise to larger detection signals, facilitating the operation of devices without saturation of the sensors. Studies on the fundamental effects of an external magnetic field on the evolution of the shape of droplets, as enabled by the non-visual monitoring capability of the device, provides crucial information for future development of a magnetofluidic device for multiplexed assays.

Published

2015