Your search keyword '"Heigl, M."' showing total 18 results

1. Zielerreichung in der Abfallwirtschaft – digital bereitgestellte Information und Anreizsysteme als Maßnahmen zur Steigerung der Sammelquoten

Author

Badura, F. and Heigl, M.

Published

2025

2. Magnetic properties of Co/Ni-based multilayers with Pd and Pt insertion layers.

Author

Heigl, M., Wendler, R., Haugg, S. D., and Albrecht, M.

Subjects

*MAGNETIC properties, *MAGNETIC anisotropy, *MULTILAYERS, *CURIE temperature, *MAGNETIC domain, *MAGNETIZATION, *PRECIOUS metals, *PALLADIUM

Abstract

In this study, the influence of Pd and Pt insertion layers in Co/Ni multilayers (MLs) on their magnetic properties, e.g., magnetic anisotropies, saturation magnetization, coercivity, magnetic domain size, and Curie temperature, is investigated. We compare three series of [Co/Ni/X] N ML systems (X = Pd , Pt, no insertion layer), varying the individual Co layer thickness as well as the repetition number N. All three systems behave very similarly for the different Co layer thicknesses. For all systems, a maximum effective magnetic anisotropy was achieved for MLs with a Co layer thickness between 0.15 and 0.25 nm. The transition from an out-of-plane to an in-plane system occurs at about 0.4 nm of Co. While [Co(0.2 nm)/Ni(0.4 nm)] N MLs change their preferred easy magnetization axis from out-of-plane to in-plane after six bilayer repetitions, insertion of Pd and Pt results in an extension of this transition beyond 15 repetitions. The maximum effective magnetic anisotropy was more than doubled from 105 kJ/m 3 for [Co/Ni] 3 to 275 and 186 kJ/m 3 for Pt and Pd, respectively. Furthermore, the insertion layers strongly reduce the initial saturation magnetization of 1100 kA/m of Co/Ni MLs and lower the Curie temperature from 720 to around 500 K. [ABSTRACT FROM AUTHOR]

Published

2020

3. MT30 Budget Impact of Improved Perioperative Reprocessing of Surgical Sets Used in Trauma Surgery in a Major German University Hospital

Author

Forster, A, Muehlendyck, C, Battaglia, S, Brablé, J, Galvain, T, Penn, G, and Heigl, M

Published

2024

4. The effect of added lactates to quality of freshly marinated meat.

Author

Medić, H., Horvat, M., Heigl, M., Vidaček, S., Marušić, N., and Janči, T.

Subjects

TASTE testing of food, LACTATES, MEAT quality, MEAT microbiology, PEROXIDES, FATTY acid content of food, MEAT storage

Abstract

Copyright of MESO is the property of Zadruzna Stampa D.D. and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2012

5. Utjecaj dodatka laktata na kvalitetu svježe mariniranog mesa.

Author

Medić, H., Horvat, M., Heigl, M., Vidaček, S., Marušić, N., and Janči, T.

Subjects

MEAT quality, LACTATES, TASTE testing of food, MEAT microbiology, FOOD chemistry, FATTY acid content of food, MEAT storage

Abstract

Copyright of MESO is the property of Zadruzna Stampa D.D. and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2012

6. Routine tests for monitoring automated cleaning and disinfection processes: Recommendations by the quality task group (115).

Author

Amann, B., Carter, A., Diedrich, D., Forster, A., Hartwig, A., Kirmse, G., Krüger, S., Lang, J., Mock, I., Gebel, J., Heigl, M., Metzing, J., Pozo, H., Schmid, C., and Zimmermann, U.

Subjects

SURGICAL instruments, STERILIZATION (Disinfection), DISINFECTION & disinfectants, BACTERIOLOGY technique, BIOLOGICAL decontamination

Abstract

The article offers information on the routine tests for monitoring automated cleaning and disinfection processes. Topics discussed include quality of automated cleaning and disinfection, conduct of test during ongoing operations for stable process sequences, and batch-related and periodic tests like check batch protocol.

Published

2019

7. Routineprüfungen zur Überwachung des maschinellen Reinigungs- und Desinfektionsprozesses: Empfehlung des Fachausschusses Qualität (115).

Author

Amann, B., Carter, A., Diedrich, D., Forster, A., Hartwig, A., Kirmse, G., Krüger, S., Lang, J., Mock, I., Gebel, J., Heigl, M., Metzing, J., Pozo, H., Schmid, C., and Zimmermann, U.

Published

2019

8. Nonreciprocal Dzyaloshinskii-Moriya Magnetoacoustic Waves.

Author

Küß, M., Heigl, M., Flacke, L., Hörner, A., Weiler, M., Albrecht, M., and Wixforth, A.

Subjects

*TRANSMISSION of sound, *ACOUSTIC surface waves, *MAGNETOHYDRODYNAMIC waves, *THEORY of wave motion, *MAGNETIC films, *MAGNETIC fields, *SPIN waves

Abstract

We study the interaction of surface acoustic waves with spin waves in ultrathin CoFeB/Pt bilayers. Because of the interfacial Dzyaloshinskii-Moriya interaction (DMI), the spin wave dispersion is nondegenerate for oppositely propagating spin waves in CoFeB/Pt. In combination with the additional nonreciprocity of the magnetoacoustic coupling itself, which is independent of the DMI, highly nonreciprocal acoustic wave transmission through the magnetic film is observed. We systematically characterize the magnetoacoustic wave propagation in a thickness series of CoFeB(d)/Pt samples as a function of magnetic field magnitude and direction, and at frequencies up to 7 GHz. We quantitatively model our results to extract the strength of the DMI and magnetoacoustic driving fields. [ABSTRACT FROM AUTHOR]

Published

2020

9. Dipolar skyrmions and antiskyrmions of arbitrary topological charge at room temperature.

Author

Hassan M, Koraltan S, Ullrich A, Bruckner F, Serha RO, Levchenko KV, Varvaro G, Kiselev NS, Heigl M, Abert C, Suess D, and Albrecht M

Abstract

Magnetic skyrmions are localized, stable topological magnetic textures that can move and interact with each other like ordinary particles when an external stimulus is applied. The efficient control of the motion of spin textures using spin-polarized currents opened an opportunity for skyrmionic devices such as racetrack memory and neuromorphic or reservoir computing. The coexistence of skyrmions with high topological charge in the same system promises further possibilities for efficient technological applications. In this work, we directly observe dipolar skyrmions and antiskyrmions with arbitrary topological charge in Co/Ni multilayers at room temperature. We explore the dipolar-stabilized spin objects with topological charges of up to 10 and characterize their nucleation process, their energy dependence on the topological charge and the effect of the material parameters on their stability. Furthermore, our micromagnetic simulations demonstrate spin-transfer-induced motion of these spin objects, which is important for their potential device application., Competing Interests: Competing interestsThe authors declare no competing interests., (© The Author(s), under exclusive licence to Springer Nature Limited 2024.)

Published

2024

10. Modelling clinical narrative as computable knowledge: The NICE computable implementation guidance project.

Author

Scott P, Heigl M, McCay C, Shepperdson P, Lima-Walton E, Andrikopoulou E, Brunnhuber K, Cornelius G, Faulding S, McAlister B, Rowark S, South M, Thomas MR, Whatling J, Williams J, Wyatt JC, and Greaves F

Abstract

Introduction: Translating narrative clinical guidelines to computable knowledge is a long-standing challenge that has seen a diverse range of approaches. The UK National Institute for Health and Care Excellence (NICE) Content Advisory Board (CAB) aims ultimately to (1) guide clinical decision support and other software developers to increase traceability, fidelity and consistency in supporting clinical use of NICE recommendations, (2) guide local practice audit and intervention to reduce unwarranted variation, (3) provide feedback to NICE on how future recommendations should be developed., Objectives: The first phase of work was to explore a range of technical approaches to transition NICE toward the production of natively digital content., Methods: Following an initial 'collaborathon' in November 2022, the NICE Computable Implementation Guidance project (NCIG) was established. We held a series of workstream calls approximately fortnightly, focusing on (1) user stories and trigger events, (2) information model and definitions, (3) horizon-scanning and output format. A second collaborathon was held in March 2023 to consolidate progress across the workstreams and agree residual actions to complete., Results: While we initially focussed on technical implementation standards, we decided that an intermediate logical model was a more achievable first step in the journey from narrative to fully computable representation. NCIG adopted the WHO Digital Adaptation Kit (DAK) as a technology-agnostic method to model user scenarios, personae, processes and workflow, core data elements and decision-support logic. Further work will address indicators, such as prescribing compliance, and implementation in document templates for primary care patient record systems., Conclusions: The project has shown that the WHO DAK, with some modification, is a promising approach to build technology-neutral logical specifications of NICE recommendations. Implementation of concurrent computable modelling by multidisciplinary teams during guideline development poses methodological and cultural questions that are complex but tractable given suitable will and leadership., Competing Interests: Several authors work in companies that provide computable knowledge products, related data science services, patient record systems and healthcare technology consultancy: Elia Lima‐Walton and Klara Brunnhuber (Elsevier Ltd), Polly Shepperdson (First Data Bank UK Ltd), Ben McAlister (Oracle Health), Charlie McCay (Ramsey Systems), Mark Thomas (Medicaite Ltd) and Justin Whatling (Palantir Technologies Inc.). Several authors work in NICE: Susan Faulding, Felix Greaves, Michaela Heigl, Shaun Rowark and Justin Whatling. Two authors are involved in standards‐development bodies: Charlie McCay (PRSB) and Ben McAlister (HL7 UK). Philip Scott is co‐chair of MCBK‐UK. No author received funding for this project., (© 2023 The Authors. Learning Health Systems published by Wiley Periodicals LLC on behalf of University of Michigan.)

Published

2023

11. Ultrafast high-harmonic nanoscopy of magnetization dynamics.

Author

Zayko S, Kfir O, Heigl M, Lohmann M, Sivis M, Albrecht M, and Ropers C

Abstract

Light-induced magnetization changes, such as all-optical switching, skyrmion nucleation, and intersite spin transfer, unfold on temporal and spatial scales down to femtoseconds and nanometers, respectively. Pump-probe spectroscopy and diffraction studies indicate that spatio-temporal dynamics may drastically affect the non-equilibrium magnetic evolution. Yet, direct real-space magnetic imaging on the relevant timescales has remained challenging. Here, we demonstrate ultrafast high-harmonic nanoscopy employing circularly polarized high-harmonic radiation for real-space imaging of femtosecond magnetization dynamics. We map quenched magnetic domains and localized spin structures in Co/Pd multilayers with a sub-wavelength spatial resolution down to 16 nm, and strobosocopically trace the local magnetization dynamics with 40 fs temporal resolution. Our compact experimental setup demonstrates the highest spatio-temporal resolution of magneto-optical imaging to date. Facilitating ultrafast imaging with high sensitivity to chiral and linear dichroism, we envisage a wide range of applications spanning magnetism, phase transitions, and carrier dynamics., (© 2021. The Author(s).)

Published

2021

12. Dipolar-stabilized first and second-order antiskyrmions in ferrimagnetic multilayers.

Author

Heigl M, Koraltan S, Vaňatka M, Kraft R, Abert C, Vogler C, Semisalova A, Che P, Ullrich A, Schmidt T, Hintermayr J, Grundler D, Farle M, Urbánek M, Suess D, and Albrecht M

Abstract

Skyrmions and antiskyrmions are topologically protected spin structures with opposite vorticities. Particularly in coexisting phases, these two types of magnetic quasi-particles may show fascinating physics and potential for spintronic devices. While skyrmions are observed in a wide range of materials, until now antiskyrmions were exclusive to materials with D 2d symmetry. In this work, we show first and second-order antiskyrmions stabilized by magnetic dipole-dipole interaction in Fe/Gd-based multilayers. We modify the magnetic properties of the multilayers by Ir insertion layers. Using Lorentz transmission electron microscopy imaging, we observe coexisting antiskyrmions, Bloch skyrmions, and type-2 bubbles and determine the range of material properties and magnetic fields where the different spin objects form and dissipate. We perform micromagnetic simulations to obtain more insight into the studied system and conclude that the reduction of saturation magnetization and uniaxial magnetic anisotropy leads to the existence of this zoo of different spin objects and that they are primarily stabilized by dipolar interaction.

Published

2021

13. Sensitivity of PS/CoPd Janus particles to an external magnetic field.

Author

Eichler-Volf A, Alsaadawi Y, Luna FV, Khan QA, Stierle S, Xu C, Heigl M, Fekri Z, Zhou S, Zahn P, Albrecht M, Steinhart M, and Erbe A

Abstract

The dual nature of Janus particles confers fascinating properties such as a response to multiple stimuli. In this communication, we systematically study the sensitivity to a uniform external magnetic field of isolated Janus rod-shaped and spherical particles in water confined to two dimensions. The Janus asymmetry of the particles is given by magnetic [Co(0.28 nm)/Pd(0.90 nm)] 8 multilayer films deposited onto monodisperse polystyrene (PS) nanorods and microspheres, respectively. It is shown that the particles dispersed in water respond to weak magnetic field applied in in-plane direction. Here we demonstrate that a precise control of the in-plane particle orientation can be obtained for magnetic field strengths higher than 0.1 mT for microspheres and 0.4 mT for nanorods., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2021

14. Control over self-assembled Janus clusters by the strength of magnetic field in [Formula: see text].

Author

Alsaadawi Y, Eichler-Volf A, Heigl M, Zahn P, Albrecht M, and Erbe A

Abstract

Colloidal Janus microparticles can be propelled by controlled chemical reactions on their surfaces. Such microswimmers have been used as model systems for the behavior on the microscale and as carriers for cargo to well-defined positions in hard-to-access areas. Here we demonstrate the propagation motion of clusters of magnetic Janus particles driven by the catalytic decomposition of [Formula: see text] on their metallic caps. The magnetic moments of their caps lead to certain spatial arrangements of Janus particles, which can be influenced by external magnetic fields. We investigate how the arrangement of the particles and caps determines the driven motion of the particle clusters. In addition, we show the influence of confining walls on the cluster motion, which will be encountered in any real-life biological system.

Published

2021

15. Microscopic Origin of Magnetization Reversal in Nanoscale Exchange-Coupled Ferri/Ferromagnetic Bilayers: Implications for High Energy Density Permanent Magnets and Spintronic Devices.

Author

Heigl M, Vogler C, Mandru AO, Zhao X, Hug HJ, Suess D, and Albrecht M

Abstract

Giant exchange bias shifts of several Tesla have been reported in ferrimagnetic/ferromagnetic bilayer systems, which could be highly beneficial for contemporary high energy density permanent magnets and spintronic devices. However, the lack of microscopic studies of the reversal owing to the difficulty of measuring few nanometer-wide magnetic structures in high fields precludes the assessment of the lateral size of the inhomogeneity in relation to the intended application. In this study, the magnetic reversal process of nanoscale exchange-coupled bilayer systems, consisting of a ferrimagnetic TbFeCo alloy layer and a ferromagnetic [Co/Ni/Pt] N multilayer, was investigated. In particular, minor loop measurements, probing solely on the reversal characteristics of the softer ferromagnetic layer, reveal two distinct reversal mechanisms, which depend critically on the thickness of the ferromagnetic layer. For thick layers, irreversible switching of the macroscopic minor loop is observed. The underlying microscopic origin of this reversal process was studied in detail by high-resolution magnetic force microscopy, showing that the reversal is triggered by in-plane domain walls propagating through the ferromagnetic layer. In contrast, thin ferromagnetic layers show a hysteresis-free reversal, which is nucleation-dominated due to grain-to-grain variations in magnetic anisotropy of the Co/Ni/Pt multilayer and an inhomogeneous exchange coupling with the magnetically hard TbFeCo layer, as confirmed by micromagnetic simulations., Competing Interests: The authors declare no competing financial interest., (Copyright © 2020 American Chemical Society.)

Published

2020

16. Bistability of magnetic states in Fe-Pd nanocap arrays.

Author

Aravind PB, Heigl M, Fix M, Groß F, Gräfe J, Mary A, Rajgowrav CR, Krupiński M, Marszałek M, Thomas S, Anantharaman MR, and Albrecht M

Abstract

Magnetic bistability between vortex and single domain states in nanostructures are of great interest from both fundamental and technological perspectives. In soft magnetic nanostructures, the transition from a uniform collinear magnetic state to a vortex state (or vice versa) induced by a magnetic field involves an energy barrier. If the thermal energy is large enough for overcoming this energy barrier, magnetic bistability with a hysteresis-free switching occurs between the two magnetic states. In this work, we tune this energy barrier by tailoring the composition of FePd alloys, which were deposited onto self-assembled particle arrays forming magnetic vortex structures on top of the particles. The bifurcation temperature, where a hysteresis-free transition occurs, was extracted from the temperature dependence of the annihilation and nucleation field which increases almost linearly with Fe content of the magnetic alloy. This study provides insights into the magnetization reversal process associated with magnetic bistability, which allows adjusting the bifurcation temperature range by the material properties of the nanosystem.

Published

2019

17. The Native Material Limit of Electron and Hole Mobilities in Semiconductor Nanowires.

Author

Kinzel JB, Schülein FJ, Weiß M, Janker L, Bühler DD, Heigl M, Rudolph D, Morkötter S, Döblinger M, Bichler M, Abstreiter G, Finley JJ, Wixforth A, Koblmüller G, and Krenner HJ

Published

2016

18. Dynamic acoustic control of individual optically active quantum dot-like emission centers in heterostructure nanowires.

Author

Weiss M, Kinzel JB, Schülein FJ, Heigl M, Rudolph D, Morkötter S, Döblinger M, Bichler M, Abstreiter G, Finley JJ, Koblmüller G, Wixforth A, and Krenner HJ

Abstract

We probe and control the optical properties of emission centers forming in radial heterostructure GaAs-Al0.3Ga0.7As nanowires and show that these emitters, located in Al0.3Ga0.7As layers, can exhibit quantum-dot like characteristics. We employ a radio frequency surface acoustic wave to dynamically control their emission energy, and occupancy state on a nanosecond time scale. In the spectral oscillations, we identify unambiguous signatures arising from both the mechanical and electrical component of the surface acoustic wave. In addition, different emission lines of a single emission center exhibit pronounced anticorrelated intensity oscillations during the acoustic cycle. These arise from a dynamically triggered carrier extraction out of the emission center to a continuum in the radial heterostructure. Using finite element modeling and Wentzel-Kramers-Brillouin theory we identify quantum tunneling as the underlying mechanism. These simulation results quantitatively reproduce the observed switching and show that in our systems these emission centers are spatially separated from the continuum by >10.5 nm.

Published

2014