Your search keyword '"Ostler, Thomas"' showing total 9 results

1. Optical Receiver With Helicity-Dependent Magnetization Reversal.

Author

Azim, Zubair Al, Ostler, Thomas A., Xu, Chudong, and Roy, Kaushik

Subjects

*MAGNETIZATION, *ELECTROMAGNETIC induction, *MAGNETOCALORIC effects, *HELICITY of nuclear particles, *MAGNETIC tunnelling

Abstract

In this paper, we propose helicity-dependent switching (HDS) of magnetization in Co/Pt for an energy efficient optical receiver. Designing a low-power optical receiver for optical-to-electrical signal conversion has proven to be very challenging. Current day optical receivers use a photodiode that produces a photocurrent in response to input optical signals, and power hungry transimpedance amplifiers are required to amplify the small photocurrents. These limitations can be overcome by using light helicity-induced switching of magnetization which can avoid the requirement of photodiodes and subsequent transimpedance amplification by sensing the change in magnetization with a magnetic tunnel junction (MTJ). Magnetization switching of a thin ferromagnet layer using circularly polarized laser pulses has recently been demonstrated which shows a one-to-one correspondence between light helicity and the magnetization state. We use these phenomena to directly switch the magnetization state of a thin Co/Pt ferromagnet layer at the receiver via circularly polarized laser pulses. The circular polarization is controlled in accordance with digital input data which establishes a one-to-one correspondence between the transmitted data and output magnetization state. The Co/Pt layer is used as the free layer of an MTJ, the resistance of which is modified by the laser pulses. Since the output magnetization state is controlled by the input data, the MTJ resistance is directly converted to a digital output signal. Our device-to-circuit level simulation results indicate that HDS-based optical receiver circuit consumes only 0.124 pJ/bit energy, which is much lower than existing techniques. [ABSTRACT FROM AUTHOR]

Published

2019

2. Ultrafast thermally induced magnetic switching in synthetic ferrimagnets.

Author

Evans, Richard F. L., Ostler, Thomas A., Chantrell, Roy W., Radu, Ilie, and Rasing, Theo

Subjects

*MAGNETIC control, *FERRIMAGNETIC materials, *MAGNETIC structure, *MAGNETIC moments, *OPTICAL switching, *ULTRASHORT laser pulses, *MAGNETIZATION

Abstract

Synthetic ferrimagnets are composite magnetic structures formed from two or more anti-ferromagnetically coupled magnetic sublattices with different magnetic moments. Here, we report on atomistic spin simulations of the laser-induced magnetization dynamics on such synthetic ferrimagnets and demonstrate that the application of ultrashort laser pulses leads to sub-picosecond magnetization dynamics and all-optical switching in a similar manner as in ferrimagnetic alloys. Moreover, we present the essential material properties for successful laser-induced switching, demonstrating the feasibility of using a synthetic ferrimagnet as a high density magnetic storage element without the need of a write field. [ABSTRACT FROM AUTHOR]

Published

2014

3. Crystallographically amorphous ferrimagnetic alloys: Comparing a tocaliied atornisik spin model with experiments.

Author

Ostler, Thomas A., Evans, Richard F. L., Chantrell, Roy W., Atxitia, Unai, Chubykalo-Fesenko, Oksana, Radu, Ilie, Abrudan, Radu, Radu, Florin, Tsukamoto, Arata, Itoh, A., Kirilyuk, Andrei, Rasing, Theo, and Kimel, Alexey

Subjects

*FERROMAGNETISM, *MAGNETOOPTICS, *CIRCULAR dichroism, *PARAMAGNETISM, *MAGNETIZATION

Abstract

We present a computational model of crystallographically amorphous ferrimagnetic alloys using a stochastic Landau-Lifshitz-Gilbert equation of motion for atomistic spins and an atomistic spin Hamiltonian with Heisenberg exchange. The spontaneous equilibrium magnetization is calculated and a comparison with a mean field model is made. The simulations show excellent agreement with experiments on GdFeCo using x-ray magnetic circular dichroism to determine the individual sublattice magnetizations. The calculated temperature dependence of the magnetization shows a polarization of the Gd sublattice leading to a common Curie temperature, in agreement with the experimental data. The intersublattice exchange is shown to be an important energy transfer channel for ultrafast dynamics. [ABSTRACT FROM AUTHOR]

Published

2011

4. Ultrafast opto-magnetic effects in the extreme ultraviolet spectral range.

Author

Hennecke, Martin, von Korff Schmising, Clemens, Yao, Kelvin, Jal, Emmanuelle, Vodungbo, Boris, Chardonnet, Valentin, Légaré, Katherine, Capotondi, Flavio, Naumenko, Denys, Pedersoli, Emanuele, Lopez-Quintas, Ignacio, Nikolov, Ivaylo P., Raimondi, Lorenzo, De Ninno, Giovanni, Salemi, Leandro, Ruta, Sergiu, Chantrell, Roy, Ostler, Thomas, Pfau, Bastian, and Engel, Dieter

Subjects

*FARADAY effect, *MAGNETIC materials, *ULTRAVIOLET radiation, *SPIN-orbit interactions, *MAGNETISM

Abstract

Coherent light-matter interactions mediated by opto-magnetic phenomena like the inverse Faraday effect (IFE) are expected to provide a non-thermal pathway for ultrafast manipulation of magnetism on timescales as short as the excitation pulse itself. As the IFE scales with the spin-orbit coupling strength of the involved electronic states, photo-exciting the strongly spin-orbit coupled core-level electrons in magnetic materials appears as an appealing method to transiently generate large opto-magnetic moments. Here, we investigate this scenario in a ferrimagnetic GdFeCo alloy by using intense and circularly polarized pulses of extreme ultraviolet radiation. Our results reveal ultrafast and strong helicity-dependent magnetic effects which are in line with the characteristic fingerprints of an IFE, corroborated by ab initio opto-magnetic IFE theory and atomistic spin dynamics simulations. Coherent light-matter interactions mediated by opto-magnetic phenomena like the inverse Faraday effect are expected to provide a non-thermal pathway for ultrafast manipulation of magnetism. The authors use intense and circularly polarized pulses of extreme ultraviolet radiation to induce particularly strong effects in a ferrimagnetic GdFeCo alloy. [ABSTRACT FROM AUTHOR]

Published

2024

5. Modeling the thickness dependence of the magnetic phase transition temperature in thin FeRh films.

Author

Ostler, Thomas Andrew, Barton, Craig, Thomson, Thomas, and Hrkac, Gino

Subjects

*MAGNETIC transitions, *TEMPERATURE, *MAGNESIUM oxide

Abstract

FeRh and its first-order phase transition can open new routes for magnetic hybrid materials and devices under the assumption that it can be exploited in ultra-thin-film structures. Motivated by experimental measurements showing an unexpected increase in the phase transition temperature with decreasing thickness of FeRh on top of MgO, we develop a computational model to investigate strain effects of FeRh in such magnetic structures. Our theoretical results show that the presence of the MgO interface results in a strain that changes the magnetic configuration which drives the anomalous behavior. [ABSTRACT FROM AUTHOR]

Published

2017

6. Effects of interactions on the relaxation processes in magnetic nanostructures.

Author

Atkinson, Lewis J., Ostler, Thomas A., Hovorka, O., Wang, K. K., Lu, B., Ju, G. P., Hohlfeld, J., Bergman, B., Koopmans, B., and Chantrell, Roy W.

Subjects

*MAGNETIC nanoparticles, *MAGNETIC storage, *OPTICAL resonance, *MAGNETIC relaxation, *MAGNETOSTATICS

Abstract

Controlling the relaxation of magnetization in magnetic nanostructures is key to optimizing magnetic storage device performance. This relaxation is governed by both intrinsic and extrinsic relaxation mechanisms and with the latter strongly dependent on the interactions between the nanostructures. In the present work we investigate laser induced magnetization dynamics in a broadband optical resonance type experiment revealing the role of interactions between nanostructures on the relaxation processes of granular magnetic structures. The results are corroborated by constructing a temperature dependent numerical micromagnetic model of magnetization dynamics based on the Landau-Lifshitz-Bloch equation. The model predicts a strong dependence of damping on the key material properties of coupled granular nanostructures in good agreement with the experimental data. We show that the intergranular, magnetostatic and exchange interactions provide a large extrinsic contribution to the damping. Finally we show that the mechanism can be attributed to an increase in spin-wave degeneracy with the ferromagnetic resonance mode as revealed by semianalytical spin-wave calculations. [ABSTRACT FROM AUTHOR]

Published

2016

7. Simulations of magnetization reversal in FM/AFM bilayers with THz frequency pulses.

Author

Hirst, Joel, Ruta, Sergiu, Jackson, Jerome, and Ostler, Thomas

Subjects

*MAGNETIZATION reversal, *DATA warehousing, *PHASE diagrams, *MAGNETORESISTANCE, *MAGNETIZATION, *BILAYER lipid membranes

Abstract

It is widely known that antiferromagnets (AFMs) display a high frequency response in the terahertz (THz) range, which opens up the possibility for ultrafast control of their magnetization for next generation data storage and processing applications. However, because the magnetization of the different sublattices cancel, their state is notoriously difficult to read. One way to overcome this is to couple AFMs to ferromagnets—whose state is trivially read via magneto-resistance sensors. Here we present conditions, using theoretical modelling, that it is possible to switch the magnetization of an AFM/FM bilayer using THz frequency pulses with moderate field amplitude and short durations, achievable in experiments. Consistent switching is observed in the phase diagrams for an order of magnitude increase in the interface coupling and a tripling in the thickness of the FM layer. We demonstrate a range of reversal paths that arise due to the combination of precession in the materials and the THz-induced fields. Our analysis demonstrates that the AFM drives the switching and results in a much higher frequency dynamics in the FM due to the exchange coupling at the interface. The switching is shown to be robust over a broad range of temperatures relevant for device applications. [ABSTRACT FROM AUTHOR]

Published

2023

8. Local thermoelectric response from a single Ne'el domain wall.

Author

Puttock, Robert, Barton, Craig, Saugar, Elias, Klapetek, Petr, Fernández-Scarioni, Alexander, Freitas, Paulo, Schumacher, Hans W., Ostler, Thomas, Chubykalo-Fesenko, Oksana, and Kazakova, Olga

Subjects

*CONDENSED matter physics, *NERNST effect, *NANOWIRES

Abstract

The article presents a analysis of the thermoelectric response from a single trapped domain wall with the use of a heated scanning probe. Topics discussed include the importance of resolving the nanoscale magnetization in addressing the underconstrained problem of determining the spin texture, symmetry of magnetothermoelectric effects, and the key features of the scanning thermoelectric microscopy technique.

Published

2022

9. Roles of heating and helicity in ultrafast all-optical magnetization switching in TbFeCo.

Author

Lu, Xianyang, Zou, Xiao, Hinzke, Denise, Liu, Tao, Wang, Yichuan, Cheng, Tuyuan, Wu, Jing, Ostler, Thomas A., Cai, Jianwang, Nowak, Ulrich, Chantrell, Roy W., Zhai, Ya, and Xu, Yongbing

Subjects

*HELICITY (Chemistry), *KERR electro-optical effect, *CURRENT-induced magnetization switching, *QUANTUM spin models, *TERBIUM spectra

Abstract

Using the time-resolved magneto-optical Kerr effect method, helicity-dependent all-optical magnetization switching (HD-AOS) is observed in ferrimagnetic TbFeCo films. Our results reveal the individual roles of the thermal and nonthermal effects after a single circularly polarized laser pulse. The evolution of this ultrafast switching occurs over different time scales, and a defined magnetization reversal time of 460 fs is shown—the fastest ever observed. Micromagnetic simulations based on a single macro-spin model, taking into account both heating and the inverse Faraday effect, are performed which reproduce HD-AOS demonstrating a linear path for magnetization reversal. [ABSTRACT FROM AUTHOR]

Published

2018