Your search keyword '"Stahn, J."' showing total 9 results

1. Eliminating the spin-down critical angle in polarizing neutron optics for expanding the polarization bandwidth

Author

Zubayer, A., Ghafoor, N., Glavic, A., Stahn, J., Lorentzon, M., Febvrier, A. Le, Eklund, P., Birch, J., and Eriksson, F.

Subjects

Condensed Matter - Materials Science

Abstract

Polarized neutron scattering is a very important analysis technique for studies of magnetism, spintronics, and high-sensitivity measurements, among others, offering invaluable information. Yet, the efficiency of such experiments rely on the performance of the polarizing neutron optics to provide high reflectivity and polarization. Presently, state-of-the-art polarizers like Fe/Si supermirrors are not able to polarize neutrons at low scattering angles in a monochromatic beam or able to polarize neutrons with a variety of wavelengths as for a non-monochromatic beam. To overcome this limitation, it is suggested to use Co/Ti multilayers on Ti substrates owing to their favorable scattering length density characteristics. It is shown that this approach enables a wavelength bandwidth several times larger than achievable with state-of-the-art materials on Si or glass substrates. Consequently, enabling the possibility of polarizing neutrons across an extended wavelength range, including those with very high wavelengths.

Published

2024

2. Neutron optical tuning of Fe/11B4CTi multilayers for optimal polarization and increased reflectivity for polarizing neutron optics

Author

Zubayer, A., Ghafoor, N., Thorarinsdottir, K. A., Glavic, A., Stahn, J., Nagy, G., Vorobiev, A., Magnus, F., Birch, J., and Eriksson, F.

Subjects

Condensed Matter - Materials Science

Abstract

The concept of scattering length density tuning for improved polarization is investigated for Fe/11B4CTi multilayers and compared to the commonly used Fe/Si system in polarizing multilayer neutron optics. X-ray and neutron reflectivity, magnetization, and neutron polarization have been measured on such multilayers, highlighting differences from conventional Fe/Si multilayers. The multilayer systems were deposited with 25 {\AA} period thickness, a layer thickness ratio of 0.35 and 20 periods, using ion-assisted DC magnetron sputtering. Replacing Si with 11B4CTi for these multilayers showed an increase in reflectivity due to a reduction in interface width. By tuning the ratio between 11B4C and Ti in the non-magnetic layers, a broad range of scattering length density values was achieved, facilitating scattering length density contrast matching between layers for spin-down neutrons, thereby enhancing polarization. These findings demonstrate the potential of Fe/11B4CTi multilayers as a promising option for polarizing neutron optics and highlight the concept of scattering length density tuning in a large range using 11B4CTi.

Published

2024

3. Multi-Blade detector with VMM3a-ASIC-based readout: installation and commissioning at the reflectometer Amor at PSI

Author

Piscitelli, F., Moradi, F. Ghazi, Alves, F. S., Christensen, M. J., Hrivnak, J., Johansson, A., Fissum, K., Lai, C. C., Martinez, A. Monera, Pfeiffer, D., Shahu, E., Stahn, J., and Svensson, P. O.

Subjects

Physics - Instrumentation and Detectors

Abstract

The Multi-Blade (MB) Boron-10-based neutron detector is the chosen technology for three instruments at the European Spallation Source (ESS): the two ESS reflectometers, ESTIA and FREIA, and the Test Beam Line. A fourth MB detector has been built, installed and commissioned for the user operation of the reflectometer Amor at PSI (Switzerland). Amor can be considered a downscaled version of the ESS reflectometer ESTIA. They are based on the same Selene guide concept, optimized for performing focusing reflectometry on small samples. The experience gained at Amor is invaluable for the future deployment of the MB detector at the ESS. This manuscript describes the MB detector construction and installation at Amor along with the readout electronics chain based on the VMM3a ASIC. The readout chain deployed at Amor is equivalent of that of the ESS, including the readout master module (RMM), event-formation-units (EFUs), Kafka, FileWriter and live visualisation tools., Comment: 16 pages, 12 figures

Published

2024

4. Reflective, polarizing, and magnetically soft amorphous Fe/Si multilayer neutron optics with isotope-enriched 11B4C inducing atomically flat interfaces

Author

Zubayer, A., Ghafoor, N., Thórarinsdóttir, K. A., Stendahl, S., Glavic, A., Stahn, J., Nagy, G., Greczynski, G., Schwartzkopf, M., Febvrier, A. Le, Eklund, P., Birch, J., Magnus, F., and Eriksson, F.

Subjects

Condensed Matter - Materials Science

Abstract

The utilization of polarized neutrons is of great importance in scientific disciplines spanning materials science, physics, biology, and chemistry. Polarization analysis offers insights into otherwise unattainable sample information such as magnetic domains and structures, protein crystallography, composition, orientation, ion-diffusion mechanisms, and relative location of molecules in multicomponent biological systems. State-of-the-art multilayer polarizing neutron optics have limitations, particularly low specular reflectivity and polarization at higher scattering vectors/angles, and the requirement of high external magnetic fields to saturate the polarizer magnetization. Here, we show that by incorporating 11B4C into Fe/Si multilayers, amorphization and smooth interfaces can be achieved, yielding higher neutron reflectivity, less diffuse scattering and higher polarization. Magnetic coercivity is eliminated, and magnetic saturation can be reached at low external fields (>2 mT). This approach offers prospects for significant improvement in polarizing neutron optics, enabling; nonintrusive positioning of the polarizer, enhanced flux, increased data accuracy, and further polarizing/analyzing methods at neutron scattering facilities.

Published

2023

5. Multi-Blade detector with VMM3a-ASIC-based readout: installation and commissioning at the reflectometer Amor at PSI

Author

Piscitelli, F., primary, Ghazi Moradi, F., additional, Alves, F.S., additional, Christensen, M.J., additional, Hrivnak, J., additional, Johansson, A., additional, Fissum, K., additional, Lai, C.C., additional, Monera Martinez, A., additional, Pfeiffer, D., additional, Shahu, E., additional, Stahn, J., additional, and Svensson, P.O., additional

Published

2024

6. Unravelling the Origin of Ultra-Low Conductivity in SrTiO3 Thin Films: Sr Vacancies and Ti on A-Sites Cause Fermi Level Pinning

Author

Morgenbesser, M., Viernstein, A., Schmid, A., Herzig, C., Kubicek, M., Taibl, S., Bimashofer, G., Stahn, J., Antonio Fernandes Vaz, C., Döbeli, M., Biautti, F., Dios Sirvent, J., (0000-0001-7933-7295) Liedke, M. O., (0000-0003-3674-0767) Butterling, M., Kamiński, M., Tolkiehn, M., Vonk, V., Stierle, A., (0000-0001-7575-3961) Wagner, A., Tarancon, A., Limbeck, A., Fleig, J., Morgenbesser, M., Viernstein, A., Schmid, A., Herzig, C., Kubicek, M., Taibl, S., Bimashofer, G., Stahn, J., Antonio Fernandes Vaz, C., Döbeli, M., Biautti, F., Dios Sirvent, J., (0000-0001-7933-7295) Liedke, M. O., (0000-0003-3674-0767) Butterling, M., Kamiński, M., Tolkiehn, M., Vonk, V., Stierle, A., (0000-0001-7575-3961) Wagner, A., Tarancon, A., Limbeck, A., and Fleig, J.

Abstract

Different SrTiO3 thin films are investigated to unravel the nature of ultra-low conductivities recently found in SrTiO3 films prepared by pulsed laser deposition. Impedance spectroscopy reveals electronically pseudo-intrinsic conductivities for a broad range of different dopants (Fe, Al, Ni) and partly high dopant concentrations up to several percent. Using inductively-coupled plasma optical emission spectroscopy and reciprocal space mapping, a severe Sr deficiency is found and positron annihilation lifetime spectroscopy revealed Sr vacancies as predominant point defects. From synchrotron-based X-ray standing wave and X-ray absorption spectroscopy measurements, a change in site occupation is deduced for Fe-doped SrTiO3 films, accompanied by a change in the dopant type. Based on these experiments, a model is deduced, which explains the almost ubiquitous pseudo-intrinsic conductivity of these films. Sr deficiency is suggested as key driver by introducing Sr vacancies and causing site changes (FeSr and TiSr) to accommodate nonstoichiometry. Sr vacancies act as mid-gap acceptor states, pinning the Fermi level, provided that additional donor states (most probably Ti_Sr) are present. Defect chemical modeling revealed that such a Fermi level pinning also causes a self-limitation of the Ti site change and leads to a very robust pseudo-intrinsic situation, irrespective of Sr/Ti ratios and doping.

Published

2022

7. Self-Diffusion of Ge in Amorphous Ge x Si 1- x Films Studied In Situ by Neutron Reflectometry.

Author

Hüger E, Stahn J, and Schmidt H

Abstract

Ge x Si 1- x alloys are gaining renewed interest for many applications in electronics and optics, especially for miniaturized devices showing quantum size effects. Point defects and atomic diffusion play a crucial role in miniaturized and metastable systems. In the present work, Ge self-diffusion in sputter deposited amorphous Ge x Si 1- x alloys is studied in situ as a function of Ge content x = 0.13, 0.43, 0.8, and 1.0 by neutron reflectometry. The determined Ge self-diffusivities obey the Arrhenius law in the investigated temperature ranges. The higher the Ge content x , the higher the Ge self-diffusivity at the same temperature. The activation enthalpy decreases with x from 4.4 eV for self-diffusion in pure silicon films to about 2 eV self-diffusion in Ge 0.8 Si 0.2 and Ge. The decrease of the activation enthalpy for amorphous Ge x Si 1- x is similar to the case of crystalline Ge x Si 1- x . Possible explanations are discussed., Competing Interests: The authors declare no competing financial interest., (© 2024 The Authors. Published by American Chemical Society.)

Published

2024

8. Reflective, polarizing, and magnetically soft amorphous neutron optics with 11 B-enriched B 4 C.

Author

Zubayer A, Ghafoor N, Thórarinsdóttir KA, Stendahl S, Glavic A, Stahn J, Nagy G, Greczynski G, Schwartzkopf M, Le Febvrier A, Eklund P, Birch J, Magnus F, and Eriksson F

Abstract

The utilization of polarized neutrons is of great importance in scientific disciplines spanning materials science, physics, biology, and chemistry. However, state-of-the-art multilayer polarizing neutron optics have limitations, particularly low specular reflectivity and polarization at higher scattering vectors/angles, and the requirement of high external magnetic fields to saturate the polarizer magnetization. Here, we show that, by incorporating 11 B 4 C into Fe/Si multilayers, amorphization and smooth interfaces can be achieved, yielding higher neutron reflectivity, less diffuse scattering, and higher polarization. Magnetic coercivity is eliminated, and magnetic saturation can be reached at low external fields (>2 militesla). This approach offers prospects for substantial improvement in polarizing neutron optics with nonintrusive positioning of the polarizer, enhanced flux, increased data accuracy, and further polarizing/analyzing methods at neutron scattering facilities.

Published

2024

9. Stabilizing effects of Ag doping on structure and thermal stability of FeN thin films.

Author

Niti N, Kumar Y, Seema S, Reddy VR, Vas JV, Gupta S, Stahn J, Gupta A, and Gupta M

Abstract

In this work, we investigated the effect of Ag doping (2-20 at.%) on the phase formation of iron mononitride (FeN) thin films. Together with deposition of FeN using reactive dc magnetron sputtering, Ag was also co-sputtered at various doping levels between 2-20 at.%. We found that doping of Ag around 5 at.% is optimum to not only improve the thermal stability of FeN but also to reduce intrinsic defects that are invariably present in (even in epitaxial) FeN. Conversion electron Mössbauer spectroscopy and N K-edge x-ray near edge absorption measurements clearly reveal a reduction of defects in Ag doped FeN samples. Moreover, Fe self-diffusion measurements carried out using secondary ion mass spectroscopy depth-profiling and polarized neutron reflectivity in 57 Fe enriched samples exhibit an appreciable reduction in Fe self-diffusion in Ag doped FeN samples. Ag being immiscible with Fe and non-reactive with N, occupies grain-boundary positions as nanoparticles and prohibits the fast Fe self-diffusion in FeN., (© 2021 IOP Publishing Ltd.)

Published

2021