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1. Back-hopping in Spin-Transfer-Torque switching of perpendicularly magnetized tunnel junctions

Author

Devolder, T., Bultynck, O., Bouquin, P., Nguyen, V. D., Rao, S., Wan, D., Sorée, B., Radu, I. P., Kar, G. S., and Couet, S.

Subjects
Condensed Matter - Materials Science, Physics - Applied Physics
Abstract

We analyse the phenomenon of back-hopping in spin-torque induced switching of the magnetization in perpendicularly magnetized tunnel junctions. The analysis is based on single-shot time-resolved conductance measurements of the pulse-induced back-hopping. Studying several material variants reveals that the back-hopping is a feature of the nominally fixed system of the tunnel junction. The back-hopping is found to proceed by two sequential switching events that lead to a final state P' of conductance close to --but distinct from-- that of the conventional parallel state. The P' state does not exist at remanence. It generally relaxes to the conventional antiparallel state if the current is removed. The P' state involves a switching of the sole spin-polarizing part of the fixed layers. The analysis of literature indicates that back-hopping occurs only when the spin-polarizing layer is too weakly coupled to the rest of the fixed system, which justifies a posteriori the mitigation strategies of back-hopping that were implemented empirically in spin-transfer-torque magnetic random access memories., Comment: submitted to Phys Rev. B

Published
2020
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4. Quantum Transport in a Nanosize Silicon-on-Insulator Metal-Oxide-Semiconductor

Author

Croitoru, M. D., Gladilin, V. N., Fomin, V. M., Devreese, J. T., Magnus, W., Schoenmaker, W., and Soree, B.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

An approach is developed for the determination of the current flowing through a nanosize silicon-on-insulator (SOI) metal-oxide-semiconductor field-effect transistors (MOSFET). The quantum mechanical features of the electron transport are extracted from the numerical solution of the quantum Liouville equation in the Wigner function representation. Accounting for electron scattering due to ionized impurities, acoustic phonons and surface roughness at the Si/SiO2 interface, device characteristics are obtained as a function of a channel length. From the Wigner function distributions, the coexistence of the diffusive and the ballistic transport naturally emerges. It is shown that the scattering mechanisms tend to reduce the ballistic component of the transport. The ballistic component increases with decreasing the channel length., Comment: 21 pages, 8 figures, E-mail addresses: devreese@uia.ua.ac.be

Published
2003
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5. Quantum transport in the cylindrical nanosize silicon-based MOSFET

Author

Balaban, S. N., Pokatilov, E. P., Fomin, V. M., Gladilin, V. N., Devreese, J. T., Magnus, W., Schoenmaker, W., Van Rossum, M., and Soree, B.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

A model is developed for a detailed investigation of the current flowing through a cylindrical nanosize MOSFET with a close gate electrode. The quantum mechanical features of the lateral charge transport are described by Wigner distribution function which is explicitly dealing with electron scattering due to acoustic phonons and acceptor impurities. A numerical simulation is carried out to obtain a set of I-V characteristics for various channel lengths. It is demonstrated that inclusion of the collision term in the numerical simulation is important for low values of the source-drain voltage. The calculations have further shown that the scattering leads to an increase of the electron density in the channel thereby smoothing out the threshold kink in I-V characteristics. An analysis of the electron phase-space distribution shows that scattering does not prevent electrons from flowing through the channel as a narrow stream, and that features of both ballistic and diffusive transport may be observed simultaneously., Comment: 24 pages, 8 figures, E-mail addresses: devreese@uia.ua.ac.be, fomin@uia.ua.ac.be

Published
2000

14. Voltage-controlled coupling of flux states in superconducting rings.

Author

Kenawy, A, Magnus, W, Milošević, M V, and Sorée, B

Subjects
JOSEPHSON effect, COOPER pair, JOSEPHSON junctions, SUPERCONDUCTING circuits, SUPERCONDUCTING quantum interference devices, QUBITS, SQUIDS
Abstract

Superconducting circuits represent a versatile playground to explore novel quantum phenomena and a platform to realize quantum bits (qubits). Superconducting qubits hinge on the coherent tunneling of Cooper pairs across the insulating barrier of a Josephson junction. This qubit implementation is, however, plagued with the variability of the fabricated junction, along with the need for magnetic tunability of the qubit transition frequency. Alternatively, a dual to the Josephson effect—referred to as quantum phase slips—allows for a coherent coupling of flux states and has been used to build phase-slip qubits. In this paper, we propose coupling flux states of a superconducting ring using a bias voltage. By solving the time-dependent Ginzburg–Landau equations, we demonstrate that the bias voltage locally suppresses the density of Cooper pairs, thereby forming a weak link where phase slips occur. Moreover, we show that a voltage-biased superconducting ring serves as an electrically-controlled magnetic memory. The work presented in this paper is an important step towards realizing electrically-tunable superconducting devices, such as qubits and SQUIDs. [ABSTRACT FROM AUTHOR]

Published
2020
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15. Theory of hole mobility in strained Ge and III-V p-channel inversion layers with high-κ insulators.

Author

Yan Zhang, Fischetti, M. V., Sorée, B., and O'Regan, T.

Subjects
ELECTRIC insulators & insulation research, SCATTERING (Physics), PHONON scattering, QUANTUM perturbations
Abstract

We present a comprehensive investigation of the low-field hole mobility in strained Ge and III-V (GaAs, GaSb, InSb, and In1-xGaxAs) p-channel inversion layers with both SiO2 and high-κ insulators. The valence (sub)band structure of Ge and III-V channels, relaxed and under biaxial strain (tensile and compressive) is calculated using an efficient self-consistent method based on the six-band k·p perturbation theory. The hole mobility is then computed using the Kubo-Greenwood formalism accounting for nonpolar hole-phonon scattering (acoustic and optical), surface roughness scattering, polar phonon scattering (III-Vs only), alloy scattering (alloys only) and remote phonon scattering, accounting for multisubband dielectric screening. As expected, we find that Ge and III-V semiconductors exhibit a mobility significantly larger than the 'universal' Si mobility. This is true for MOS systems with either SiO2 or high-κ insulators, although the latter ones are found to degrade the hole mobility compared to SiO2 due to scattering with interfacial optical phonons. In addition, III-Vs are more sensitive to the interfacial optical phonons than Ge due to the existence of the substrate polar phonons. Strain-especially biaxial tensile stress for Ge and biaxial compressive stress for III-Vs (except for GaAs)-is found to have a significant beneficial effect with both SiO2 and HfO2. Among strained p-channels, InSb exhibits the largest mobility enhancement. In0.7Ga0.3As also exhibits an increased hole mobility compared to Si, although the enhancement is not as large. Finally, our theoretical results are favorably compared with available experimental data for a relaxed Ge p-channel with a HfO2 insulator. [ABSTRACT FROM AUTHOR]

Published
2010
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16. Calculation of the electron mobility in III-V inversion layers with high-κ dielectrics.

Author

O'Regan, T. P., Fischetti, M. V., Sorée, B., Jin, S., Magnus, W., and Meuris, M.

Subjects
ELECTRON mobility, SEMICONDUCTORS, DIELECTRICS, PHONONS, PLASMONS (Physics)
Abstract

We calculate the electron mobility for a metal-oxide-semiconductor system with a metallic gate, high-κ dielectric layer, and III-V substrate, including scattering with longitudinal-optical (LO) polar-phonons of the III-V substrate and with the interfacial excitations resulting from the coupling of insulator and substrate optical modes among themselves and with substrate plasmons. In treating scattering with the substrate LO-modes, multisubband dynamic screening is included and compared to the dielectric screening in the static limit and with the commonly used screening model obtained by defining an effective screening wave vector. The electron mobility components limited by substrate LO phonons and interfacial modes are calculated for In0.53Ga0.47As and GaAs substrates with SiO2 and HfO2 gate dielectrics. The mobility components limited by the LO-modes and interfacial phonons are also investigated as a function of temperature. Scattering with surface roughness, fixed interface charge, and nonpolar-phonons is also included to judge the relative impact of each scattering mechanism in the total mobility for In0.53Ga0.47As with HfO2 gate dielectric. We show that InGaAs is affected by interfacial-phonon scattering to an extent larger than Si, lowering the expected performance, but probably not enough to question the technological relevance of InGaAs. [ABSTRACT FROM AUTHOR]

Published
2010
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17. Physical modeling of strain-dependent hole mobility in Ge p-channel inversion layers.

Author

Zhang, Y., Fischetti, M. V., Sorée, B., Magnus, W., Heyns, M., and Meuris, M.

Subjects
PHYSICS research, SEMICONDUCTORS, HOLES (Electron deficiencies), CRYSTAL defects, ELECTRON-hole droplets, EXCESS electrons, PHONONS, SCATTERING (Physics)
Abstract

We present comprehensive calculations of the low-field hole mobility in Ge p-channel inversion layers with SiO2 insulator using a six-band k·p band-structure model. The cases of relaxed, biaxially, and uniaxially (both tensily and compressively) strained Ge are studied employing an efficient self-consistent method—making use of a nonuniform spatial mesh and of the Broyden second method—to solve the coupled envelope-wave function k·p and Poisson equations. The hole mobility is computed using the Kubo–Greenwood formalism accounting for nonpolar hole-phonon scattering and scattering with interfacial roughness. Different approximations to handle dielectric screening are also investigated. As our main result, we find a large enhancement (up to a factor of 10 with respect to Si) of the mobility in the case of uniaxial compressive stress similarly to the well-known case of Si. Comparison with experimental data shows overall qualitative agreement but with significant deviations due mainly to the unknown morphology of the rough Ge-insulator interface, to additional scattering with surface optical phonon from the high-κ insulator, to Coulomb scattering interface traps or oxide charges—ignored in our calculations—and to different channel structures employed. [ABSTRACT FROM AUTHOR]

Published
2009
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18. Quantum transport in a nanosize double-gate metal-oxide-semiconductor field-effect transistor.

Author

Croitoru, M. D., Gladilin, V. N., Fomin, V. M., Devreese, J. T., Magnus, W., Schoenmaker, W., and Sorée, B.

Subjects
TRANSISTORS, NANOCRYSTALS, QUANTUM chemistry, PHONONS, ELECTRON scattering, SURFACE roughness, STURM-Liouville equation
Abstract

A model for the nanosize double-gate silicon-on-insulator metal-oxide-semiconductor field-effect transistors is developed, which enables both physical accuracy and flexibility. The quantum Liouville equation in the Wigner function representation has been used to deal with the quantum transport problem. Accounting for electron scattering due to ionized impurities, acoustic phonons, and surface roughness at the Si/SiO2 interface, device characteristics are obtained as a function of structure parameters. From the analysis of the Wigner function, the coexistence of diffusive and ballistic transport naturally emerges. The obtained I-V characteristics show that the double-gate device is a potential structure for ultimate complementary metal-oxide-semiconductor scaling. [ABSTRACT FROM AUTHOR]

Published
2004
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19. Quantum transport in a nanosize silicon-on-insulator metal-oxide-semiconductor field-effect transistor.

Author

Croitoru, M. D., Gladilin, V. N., Fomin, V. M., Devreese, J. T., Magnus, W., Schoenmaker, W., and Sorée, B.

Subjects
SILICON-on-insulator technology, METAL oxide semiconductor field-effect transistors, PHYSICS
Abstract

An approach is developed for the determination of the current flowing through a nanosize silicon-on-insulator metal-oxide-semiconductor field-effect transistors. The quantum-mechanical features of the electron transport are extracted from the numerical solution of the quantum Liouville equation in the Wigner function representation. Accounting for electron scattering due to ionized impurities, acoustic phonons, and surface roughness at the Si/SiO[sub 2] interface, device characteristics are obtained as a function of a channel length. From the Wigner function distributions, the coexistence of the diffusive and the ballistic transport naturally emerges. It is shown that the scattering mechanisms tend to reduce the ballistic component of the transport. The ballistic component increases with decreasing the channel length. [ABSTRACT FROM AUTHOR]

Published
2003
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20. Resistivity scaling in metallic thin films and nanowires due to grain boundary and surface roughness scattering

Author

Moors, Kristof, Sorée, B., Magnus, W., Moors, Kristof, Sorée, B., and Magnus, W.

Abstract

A modeling approach, based on an analytical solution of the semiclassical multi-subband Boltzmann transport equation, is presented to study resistivity scaling in metallic thin films and nanowires due to grain boundary and surface roughness scattering. While taking into account the detailed statistical properties of grains, roughness and barrier material as well as the metallic band structure and quantum mechanical aspects of scattering and confinement, the model does not rely on phenomenological fitting parameters.

Published
2017

23. Design and simulation of plasmonic interference-based majority gate.

Author

Raghavan, P., Doevenspeck, Jonas, Zografos, Odysseas, Gurunarayanan, Surya, Lauwereins, R., and Sorée, B.

Subjects
COMPLEMENTARY metal oxide semiconductors, SURFACE plasmons, ELECTRONIC circuit design
Abstract

Major obstacles in current CMOS technology, such as the interconnect bottleneck and thermal heat management, can be overcome by employing subwavelength-scaled light in plasmonic waveguides and devices. In this work, a plasmonic structure that implements the majority (MAJ) gate function is designed and thoroughly studied through simulations. The structure consists of three merging waveguides, serving as the MAJ gate inputs. The information of the logic signals is encoded in the phase of transmitted surface plasmon polaritons (SPP). SPPs are excited at all three inputs and the phase of the output SPP is determined by theMAJof the input phases. The operating dimensions are identified and the functionality is verified for all input combinations. This is the first reported simulation of a plasmonic MAJ gate and thus contributes to the field of optical computing at the nanoscale. [ABSTRACT FROM AUTHOR]

Published
2017
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26. Tuning the Fermi Level of SiO2-Supported Single-Layer Graphene by Thermal Annealing

Author

Nourbakhsh, Amirhasan, Cantoro, Mirco, Klekachev, A., Clemente, Francesca, Sorée, B., van der Veen, Marleen H., Vosch, Tom, Stesmans, A., Sels, Bert, De Gendt, Stefan, Nourbakhsh, Amirhasan, Cantoro, Mirco, Klekachev, A., Clemente, Francesca, Sorée, B., van der Veen, Marleen H., Vosch, Tom, Stesmans, A., Sels, Bert, and De Gendt, Stefan

Published
2010

33. A Simplified Quantum Mechanical Model for the Electron Distribution in a Si Nanowire.

Author

Grasser, Tibor, Selberherr, Siegfried, Magnus, W., Sorée, B., Pourtois, G., and Compernolle, S.

Abstract

In order to investigate the technological potential ascribed to semiconductor nanowires, it is paramount to include quantum effects into the models used to simulate carrier trans-port as well as optical and excitonic features of various nanowire layouts. In particular, one needs to determine the energy eigenvalues and eigenfunctions of the charge carriers in terms of material parameters and tunable parameters, such as the external voltages and the wire radius. As the latter may be running from a few nanometers up to a few tens of nanometers, the number of occupied subbands may substantially in-crease. Consequently, a flexible Poisson-Schrödinger solver needs to be invoked to minimize the computational burden, especially when it is to be integrated into another Simulation program. [ABSTRACT FROM AUTHOR]

Published
2007
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34. Modeling the capacitance-voltage response of In0.53Ga0.47As metal-oxide-semiconductor structures: Charge quantization and nonparabolic corrections.

Author

O'Regan, T. P., Hurley, P. K., Sorée, B., and Fischetti, M. V.

Subjects
METAL oxide semiconductors, ELECTRONIC structure, POISSON processes, POISSON'S equation, ELECTRIC capacity, CHARGE transfer
Abstract

The capacitance-voltage (C-V) characteristic is calculated for p-type In0.53Ga0.47As metal-oxide-semiconductor (MOS) structures based on a self-consistent Poisson–Schrödinger solution. For strong inversion, charge quantization leads to occupation of the satellite valleys which appears as a sharp increase in the capacitance toward the oxide capacitance. The results indicate that the charge quantization, even in the absence of interface defects (Dit), is a contributing factor to the experimental observation of an almost symmetric C-V response for In0.53Ga0.47As MOS structures. In addition, nonparabolic corrections are shown to enhance the depopulation of the Γ valley, shifting the capacitance increase to lower inversion charge densities. [ABSTRACT FROM AUTHOR]

Published
2010
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35. <atl>Quantum transport in a cylindrical sub-0.1 <f>μ</f>m silicon-based MOSFET

Author

Balaban, S.N., Pokatilov, E.P., Fomin, V.M., Gladilin, V.N., Devreese, J.T., Magnus, W., Schoenmaker, W., Van Rossum, M., and Sorée, B.

Subjects
*METAL oxide semiconductor field-effect transistors, *ELECTRODES
Abstract

A model is developed for a detailed investigation of the current flowing through a cylindrical sub-0.1 μm MOSFET with a closed gate electrode. The quantum mechanical features of the lateral charge transport are described by a Wigner distribution function which is explicitly dealing with electron scattering due to acoustic phonons and acceptor impurities. A numerical simulation is carried out to obtain a set of IV characteristics for various channel lengths. It is demonstrated that inclusion of the collision term in the numerical simulation is important for low values of the source–drain voltage. The calculations have further shown that the scattering leads to an increase of the electron density in the channel thereby smoothing out the threshold kink in the IV characteristics. An analysis of the electron phase-space distribution shows that scattering does not prevent electrons from flowing through the channel as a narrow stream, and that features of both ballistic and diffusive transport may be observed simultaneously. [Copyright &y& Elsevier]

Published
2002
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36. Modeling of Graphene for Interconnect Applications : Modellering van grafeen voor interconnectietoepassingen

Author

Contino, A, Sorée, B, and Groeseneken, G

Abstract

With the reduction of the interconnect dimensions and the increased impact of process variations and process induced damage on the circuit performance, the standard Cu/Low-k damascene interconnects are now reaching their application limits. The increase in Cu resistivity with scaling and the enhanced reliability concerns at smaller dimensions are the main drivers towards replacing Cu with an alternative material. In this Ph.D thesis work, the performance of graphene interconnects are evaluated and benchmarked against the state-of-the-art Cu/Low-k interconnects in terms of capacitance, resistance, interconnect delay, circuit delay and power consumptions. Initially, the models used to evaluate graphene's capacitance and resistance, which are a combination of original models and models from literature, are discussed. Then, the models are calibrated to both in-house and published experimental data, in order to obtain reliable predictions as a function of the input parameters. Lastly, using the calibrated models, graphene and Cu interconnects are benchmarked by varying graphene's width, quality, number of layers, doping concentration and contact configuration. We show that up to 65% capacitance reduction can be achieved when switching from Cu to graphene interconnects thanks to the reduced graphene thickness. Moreover, depending on the doping technique implemented, capacitance benefits can be obtained when assuming up to and beyond fifty graphene layers. Regarding the resistance, we demonstrate that the edge contact configuration is the preferred option for graphene interconnects, as it gives the lowest total line resistance, independently from the doping concentration or the number of graphene layers considered. When comparing graphene resistance with the one of Cu, we show how the benchmark heavily depends on the graphene quality and doping concentration. In the best case considered in this dissertation, that is HNO3 stage-1 intercalated graphene, we see that a first cross-over between Cu and graphene interconnects occurs for 17 nm interconnect width for 50 graphene layers, while only 26 layers are needed to match Cu resistance at 10 nm half-pitch interconnects. As far as the interconnect RC delay is concerned, we show that, thanks to the lower interconnect capacitance, the cross-over between Cu and graphene interconnects moves towards a lower number of layers compared to the resistance benchmark, while for circuit delay, the contact resistance between graphene and the contacting metal highly impacts graphene performance for interconnect lengths lower than 3.2 μm. Finally, we benchmark graphene against Cu for the 3 nm logic technology node, showing that up to 16% delay reduction can be achieved while also lowering the power consumption. Alternatively, 34% power reduction can be achieved for the same delay of Cu by modifying the graphene interconnect configuration. status: published

Published
2019

37. Skyrmions for Advanced Magnetic Memory and Logic: Device Modeling : Skyrmions voor geavanceerde magnetisch geheugen en logica: modellering van componenten

Author

Andrikopoulos, D, Sorée, B, and De Boeck, J

Abstract

The current thesis focuses on studying magnetic configurations called skyrmions. These can be regarded as configurations of spins that are topologically protected and have a chiral, whirling configuration. Their small size and robustness to defects, qualifies them as potential candidates for next-generation spintronic devices. Such devices can implement memory and/or logic functions. The aim of the PhD is to study the skyrmion structures and also introduce conceptual device models for skyrmion-based devices. status: published

Published
2018

38. Synthesis and high-throughput testing of multilayered supported ionic liquid catalysts for the conversion of CO2 and epoxides into cyclic carbonates

Author

Paola Agrigento, Masoumeh Taherimehr, Benjamin Sorée, Carmela Aprile, Syed Muhammad Al-Amsyar, Paolo P. Pescarmona, Michelangelo Gruttadauria, Agrigento, P, Al-Amsyar SM, Sorée B, Taherimehr, M, Gruttadauria, M, Aprile, C, and Pescarmona, PP

Subjects
Xylene, Settore CHIM/06 - Chimica Organica, Ionic liquid, Grafting, Catalysis, Cycloaddition, chemistry.chemical_compound, cyclic carbonate, chemistry, Chemical engineering, Covalent bond, Phase (matter), Organic chemistry, CO2, Octane
Abstract

Multilayered covalently supported ionic liquid phase (mlc-SILP) materials were synthesised by grafting different bis-vinylimidazolium salts on thiol-functionalised silica. These materials, which contain a cross-linked oligomeric network of imidazolium units, were characterised and tested as catalysts for the reaction of carbon dioxide with various epoxides to produce cyclic carbonates. The materials prepared by supporting a bis-imidazolium iodide salt with xylene or octane as a linker between the imidazolium units were identified as the most active catalysts and displayed high turnover numbers and improved productivity compared to known supported ionic liquid catalysts. The most promising mlc-SILP catalysts were further studied to tune the reaction conditions towards optimum catalytic performance and to investigate their versatility with different substrates and their reusability. The rapid and parallel screening of the catalysts was efficiently carried out by means of high-throughput (HT) experimentation. This journal is

Published
2014

39. Spin-Orbit Torque Vector Quantification in Nanoscale Magnetic Tunnel Junctions.

Author

Vudya Sethu KK, Yasin F, Swerts J, Sorée B, De Boeck J, Kar GS, Garello K, and Couet S

Abstract

Spin-orbit torques (SOT) allow ultrafast, energy-efficient toggling of magnetization state by an in-plane charge current for applications such as magnetic random-access memory (SOT-MRAM). Tailoring the SOT vector comprising of antidamping ( T AD ) and fieldlike ( T FL ) torques could lead to faster, more reliable, and low-power SOT-MRAM. Here, we establish a method to quantify the longitudinal ( T AD ) and transverse ( T FL ) components of the SOT vector and its efficiency χ AD and χ FL , respectively, in nanoscale three-terminal SOT magnetic tunnel junctions (SOT-MTJ). Modulation of nucleation or switching field ( B SF ) for magnetization reversal by SOT effective fields ( B SOT ) leads to the modification of SOT-MTJ hysteresis loop behavior from which χ AD and χ FL are quantified. Surprisingly, in nanoscale W/CoFeB SOT-MTJ, we find χ FL to be (i) twice as large as χ AD and (ii) 6 times as large as χ FL in micrometer-sized W/CoFeB Hall-bar devices. Our quantification is supported by micromagnetic and macrospin simulations which reproduce experimental SOT-MTJ Stoner-Wohlfarth astroid behavior only for χ FL > χ AD . Additionally, from the threshold current for current-induced magnetization switching with a transverse magnetic field, we show that in SOT-MTJ, T FL plays a more prominent role in magnetization dynamics than T AD . Due to SOT-MRAM geometry and nanodimensionality, the potential role of nonlocal spin Hall spin current accumulated adjacent to the SOT-MTJ in the mediation of T FL and χ FL amplification merits to be explored.

Published
2024
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40. Progress in Spin Logic Devices Based on Domain-Wall Motion.

Author

Vermeulen BB, Sorée B, Couet S, Temst K, and Nguyen VD

Abstract

Spintronics, utilizing both the charge and spin of electrons, benefits from the nonvolatility, low switching energy, and collective behavior of magnetization. These properties allow the development of magnetoresistive random access memories, with magnetic tunnel junctions (MTJs) playing a central role. Various spin logic concepts are also extensively explored. Among these, spin logic devices based on the motion of magnetic domain walls (DWs) enable the implementation of compact and energy-efficient logic circuits. In these devices, DW motion within a magnetic track enables spin information processing, while MTJs at the input and output serve as electrical writing and reading elements. DW logic holds promise for simplifying logic circuit complexity by performing multiple functions within a single device. Nevertheless, the demonstration of DW logic circuits with electrical writing and reading at the nanoscale is still needed to unveil their practical application potential. In this review, we discuss material advancements for high-speed DW motion, progress in DW logic devices, groundbreaking demonstrations of current-driven DW logic, and its potential for practical applications. Additionally, we discuss alternative approaches for current-free information propagation, along with challenges and prospects for the development of DW logic.

Published
2024
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41. Reduction of Magnetic Interaction Due to Clustering in Doped Transition-Metal Dichalcogenides: A Case Study of Mn-, V-, and Fe-Doped WSe 2 .

Author

Tiwari S, Van de Put M, Sorée B, Hinkle C, and Vandenberghe WG

Abstract

Using Hubbard-U-corrected density functional theory calculations, lattice Monte Carlo simulations, and spin Monte Carlo simulations, we investigate the impact of dopant clustering on the magnetic properties of WSe 2 doped with period four transition metals. We use manganese (Mn) and iron (Fe) as candidate n-type dopants and vanadium (V) as the candidate p-type dopant, substituting the tungsten (W) atom in WSe 2 . Specifically, we determine the strength of the exchange interaction in Fe-, Mn-, and V-doped WSe 2 in the presence of clustering. We show that the clusters of dopants are energetically more stable than discretely doped systems. Further, we show that in the presence of dopant clustering, the magnetic exchange interaction significantly reduces because the magnetic order in clustered WSe 2 becomes more itinerant. Finally, we show that the clustering of the dopant atoms has a detrimental effect on the magnetic interaction, and to obtain an optimal Curie temperature, it is important to control the distribution of the dopant atoms.

Published
2024
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42. Field-Free Spin-Orbit Torque Driven Switching of Perpendicular Magnetic Tunnel Junction through Bending Current.

Author

Kateel V, Krizakova V, Rao S, Cai K, Gupta M, Monteiro MG, Yasin F, Sorée B, De Boeck J, Couet S, Gambardella P, Kar GS, and Garello K

Abstract

Current-induced spin-orbit torques (SOTs) enable fast and efficient manipulation of the magnetic state of magnetic tunnel junctions (MTJs), making them attractive for memory, in-memory computing, and logic applications. However, the requirement of the external magnetic field to achieve deterministic switching in perpendicularly magnetized SOT-MTJs limits its implementation for practical applications. Here, we introduce a field-free switching (FFS) solution for the SOT-MTJ device by shaping the SOT channel to create a "bend" in the SOT current. The resulting bend in the charge current creates a spatially nonuniform spin current, which translates into inhomogeneous SOT on an adjacent magnetic free layer enabling deterministic switching. We demonstrate FFS experimentally on scaled SOT-MTJs at nanosecond time scales. This proposed scheme is scalable, material-agnostic, and readily compatible with wafer-scale manufacturing, thus creating a pathway for developing purely current-driven SOT systems.

Published
2023
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43. Lumped circuit model for inductive antenna spin-wave transducers.

Author

Vanderveken F, Tyberkevych V, Talmelli G, Sorée B, Ciubotaru F, and Adelmann C

Abstract

We derive a lumped circuit model for inductive antenna spin-wave transducers in the vicinity of a ferromagnetic medium. The model considers the antenna's Ohmic resistance, its inductance, as well as the additional inductance due to the excitation of ferromagnetic resonance or spin waves in the ferromagnetic medium. As an example, the additional inductance is discussed for a wire antenna on top of a ferromagnetic waveguide, a structure that is characteristic for many magnonic devices and experiments. The model is used to assess the scaling properties and the energy efficiency of inductive antennas. Issues related to scaling antenna transducers to the nanoscale and possible solutions are also addressed., (© 2022. The Author(s).)

Published
2022
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44. Fabry-Pérot interferometry with gate-tunable 3D topological insulator nanowires.

Author

Osca J, Moors K, Sorée B, and Serra L

Abstract

Three-dimensional topological insulator (3D TI) nanowires display remarkable magnetotransport properties that can be attributed to their spin-momentum-locked surface states such as quasiballistic transport and Aharonov-Bohm oscillations. Here, we focus on the transport properties of a 3D TI nanowire with a gated section that forms an electronic Fabry-Pérot (FP) interferometer that can be tuned to act as a surface-state filter or energy barrier. By tuning the carrier density and length of the gated section of the wire, the interference pattern can be controlled and the nanowire can become fully transparent for certain topological surface-state input modes while completely filtering out others. We also consider the interplay of FP interference with an external magnetic field, with which Klein tunneling can be induced, and transverse asymmetry of the gated section, e.g. due to a top-gated structure, which displays an interesting analogy with Rashba nanowires. Due to its rich conductance phenomenology, we propose a 3D TI nanowire with gated section as an ideal setup for a detailed transport-based characterization of 3D TI nanowire surface states near the Dirac point, which could be useful towards realizing 3D TI nanowire-based topological superconductivity and Majorana bound states., (© 2021 IOP Publishing Ltd.)

Published
2021
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45. Ab-Initio Study of Magnetically Intercalated Platinum Diselenide: The Impact of Platinum Vacancies.

Author

Reyntjens PD, Tiwari S, Van de Put ML, Sorée B, and Vandenberghe WG

Abstract

We study the magnetic properties of platinum diselenide (PtSe 2 ) intercalated with Ti, V, Cr, and Mn, using first-principle density functional theory (DFT) calculations and Monte Carlo (MC) simulations. First, we present the equilibrium position of intercalants in PtSe2 obtained from the DFT calculations. Next, we present the magnetic groundstates for each of the intercalants in PtSe2 along with their critical temperature. We show that Ti intercalants result in an in-plane AFM and out-of-plane FM groundstate, whereas Mn intercalant results in in-plane FM and out-of-plane AFM. V intercalants result in an FM groundstate both in the in-plane and the out-of-plane direction, whereas Cr results in an AFM groundstate both in the in-plane and the out-of-plane direction. We find a critical temperature of <0.01 K, 111 K, 133 K, and 68 K for Ti, V, Cr, and Mn intercalants at a 7.5% intercalation, respectively. In the presence of Pt vacancies, we obtain critical temperatures of 63 K, 32 K, 221 K, and 45 K for Ti, V, Cr, and Mn-intercalated PtSe2, respectively. We show that Pt vacancies can change the magnetic groundstate as well as the critical temperature of intercalated PtSe2, suggesting that the magnetic groundstate in intercalated PtSe2 can be controlled via defect engineering.

Published
2021
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46. Finite difference magnetoelastic simulator.

Author

Vanderveken F, Mulkers J, Leliaert J, Van Waeyenberge B, Sorée B, Zografos O, Ciubotaru F, and Adelmann C

Abstract

We describe an extension of the micromagnetic finite difference simulation software MuMax3 to solve elasto-magneto-dynamical problems. The new module allows for numerical simulations of magnetization and displacement dynamics in magnetostrictive materials and structures, including both direct and inverse magnetostriction. The theoretical background is introduced, and the implementation of the extension is discussed. The magnetoelastic extension of MuMax3 is freely available under the GNU General Public License v3., Competing Interests: No competing interests were disclosed., (Copyright: © 2021 Vanderveken F et al.)

Published
2021
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47. Anisotropic bulk and planar Heisenberg ferromagnets in uniform, arbitrarily oriented magnetic fields.

Author

Vanherck J, Sorée B, and Magnus W

Abstract

Today, further downscaling of mobile electronic devices poses serious problems, such as energy consumption and local heat dissipation. In this context, spin wave majority gates made of very thin ferromagnetic films may offer a viable alternative. However, similar downscaling of magnetic thin films eventually enforces the latter to operate as quasi-2D magnets, the magnetic properties of which are not yet fully understood, especially those related to anisotropies and external magnetic fields in arbitrary directions. To this end, we have investigated the behaviour of an easy-plane and easy-axis anisotropic ferromagnet-both in two and three dimensions-subjected to a uniform magnetic field, applied along an arbitrary direction. In this paper, a spin-[Formula: see text] Heisenberg Hamiltonian with anisotropic exchange interactions is solved using double-time temperature-dependent Green's functions and the Tyablikov decoupling approximation. We determine various magnetic properties such as the Curie temperature and the magnetization as a function of temperature and the applied magnetic field, discussing the impact of the system's dimensionality and the type of anisotropy. The magnetic reorientation transition taking place in anisotropic Heisenberg ferromagnets is studied in detail. Importantly, spontaneous magnetization is found to be absent for easy-plane 2D spin systems with short range interactions.

Published
2018
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48. Skyrmion electrical detection with the use of three-dimensional Topological Insulators/Ferromagnetic bilayers.

Author

Andrikopoulos D and Sorée B

Abstract

The effect of the magnetic skyrmion texture on the electronic transport properties of the TI surface state coupled to a thin-film FM is numerically investigated. It is shown that both Bloch (vortex) and Néel (hedgehog) skyrmion textures induce additional scattering on top of a homogeneous background FM texture which can modify the conductance of the system. The change in conductance depends on several factors including the skyrmion size, the dimensions of the FM and the exchange interaction strength. For the Néel skyrmion, the result of the interaction strongly depends on the skyrmion number N sk and the skyrmion helicity h. For both skyrmion types, significant change of the resistance can be achieved, which is in the order of kΩ.

Published
2017
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49. Exchange-driven Magnetic Logic.

Author

Zografos O, Manfrini M, Vaysset A, Sorée B, Ciubotaru F, Adelmann C, Lauwereins R, Raghavan P, and Radu IP

Abstract

Direct exchange interaction allows spins to be magnetically ordered. Additionally, it can be an efficient manipulation pathway for low-powered spintronic logic devices. We present a novel logic scheme driven by exchange between two distinct regions in a composite magnetic layer containing a bistable canted magnetization configuration. By applying a magnetic field pulse to the input region, the magnetization state is propagated to the output via spin-to-spin interaction in which the output state is given by the magnetization orientation of the output region. The dependence of this scheme with input field conditions is extensively studied through a wide range of micromagnetic simulations. These results allow different logic operating modes to be extracted from the simulation results, and majority logic is successfully demonstrated.

Published
2017
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50. Validity criteria for Fermi's golden rule scattering rates applied to metallic nanowires.

Author

Moors K, Sorée B, and Magnus W

Abstract

Fermi's golden rule underpins the investigation of mobile carriers propagating through various solids, being a standard tool to calculate their scattering rates. As such, it provides a perturbative estimate under the implicit assumption that the effect of the interaction Hamiltonian which causes the scattering events is sufficiently small. To check the validity of this assumption, we present a general framework to derive simple validity criteria in order to assess whether the scattering rates can be trusted for the system under consideration, given its statistical properties such as average size, electron density, impurity density et cetera. We derive concrete validity criteria for metallic nanowires with conduction electrons populating a single parabolic band subjected to different elastic scattering mechanisms: impurities, grain boundaries and surface roughness.

Published
2016
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