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5th internal biannual science meeting of the MLZ

Europe/Berlin
Seminarhaus Grainau

Seminarhaus Grainau

Alpspitzstr. 6, 82491 Grainau
Henrich Frielinghaus (JCNS), Robert Georgii
Description

The directorate of MLZ would like to continue the scientific exchange among the employees. The main subject this year is the upgrade program MORIS at the MLZ with special emphasis on the scientific case. We kindly ask everybody working tightly with the Maier-Leibnitz Zentrum for own suggestions of presentations within the parallel sessions of the science groups and institute meetings. Poster presentations are possible and will be presented in parallel. An after dinner scientific talk will open up for broader perspectives. 

 

The venue will be again Grainau next to the Zugspitze. The seminar will take place in the Seminarhaus-Grainau (www.seminarhaus-grainau.de) with high level standard rooms (and WLAN). We will have mostly single rooms for the participants.  Organized busses will depart from FRM-2 and serve for the return. Independent travelers can also use public transportation to Grainau (DB-Stop Untergrainau+ Taxi or Stop Zugspitzbahn Grainau + 10 minutes to walk). We think that scientific exchange must also take place within a relaxed atmosphere, therefore there will be room for discussions after dinner while having a drink. An excursion and a conference dinner will also take place.

Registration
Registration Form
Participants
  • Adrian Losko
  • Adrian Merritt
  • Adrian Merritt
  • Alan Howard
  • Alex Gustschin
  • Alexander Mutschke
  • Alexander Weber
  • Alexander Wolfertz
  • Alexandros Koutsioumpas
  • Alsu Gazizulina
  • Altantulga Buyan-Arivjikh
  • Anastasiia Fanova
  • Anastasiia Kuznetsova
  • Anastasiia Kuznetsova
  • Anatoliy Senyshyn
  • Andreas Ostermann
  • Anke Goerg
  • Apostolos Vagias
  • Arnab Majumdar
  • Astrid Schneidewind
  • Aurel Radulescu
  • Aureliano Tartaglione
  • Bastian Veltel
  • Bjoern Pedersen
  • BRIJITTA JOSEPH BONIFACE
  • Cecilia Solis
  • Christian Felder
  • Christian Franz
  • Christian Reiter
  • Christian Trageser
  • Christine Papadakis
  • Christoph Hauf
  • Christoph Hugenschmidt
  • Christopher Reck Everett
  • David Kosbahn
  • Debasish Saha
  • Denis Mettus
  • Dmitry Gorkov
  • Dominik Schwaiger
  • Fabian Apfelbeck
  • Feifei Zheng
  • Francesco Guatieri
  • Gaetano Mangiapia
  • Gilles Moehl
  • Guangjiu Pan
  • Huaying Zhong
  • Ina Lommatzsch
  • Ivana Pivarníková
  • Jean-Francois Moulin
  • Jens Klenke
  • Jens Krueger
  • Jianhui Xu
  • Jinsheng Zhang
  • Joana Rebelo Kornmeier
  • Johanna K. Jochum
  • Juergen Neuhaus
  • Julija Reitenbach
  • Junyang Chen
  • Jörg Voigt
  • Karl Zeitelhack
  • Kun Sun
  • Laura Guasco
  • Lea Westphal
  • Leon Chryssos
  • Lijiu Wang
  • Lucas Sommer
  • Lucian Mathes
  • Lukas Bauer
  • Lukas Beddrich
  • Lukas Spanier
  • Lyuyang Cheng
  • Madhu Ghanathe
  • Manuel Reus
  • Manuel Suarez Anzorena
  • Marcell Wolf
  • Markos Skoulatos
  • Markus Hoelzel
  • Martin Haese
  • Martin Müller
  • Matthew Wade
  • Michael Hofmann
  • Michael Schulz
  • Michaela Zamponi
  • Michal Dembski-Villalta
  • Michal Stekiel
  • Mohamed KEITA
  • Morgan Le Dû
  • Nebojša Zec
  • Neelima Paul
  • Nicolas Walte
  • Oleksandr Koshchii
  • Peiran Zhang
  • Peixi Wang
  • Peter Link
  • Peter Müller-Buschbaum
  • Peter Wild
  • PIKESH PAL
  • Piotr Fabrykiewicz
  • Po-Chun Chang
  • Prabhat Pant
  • Ralph Gilles
  • Richi Kumar
  • Robert Georgii
  • Ruoxuan Qi
  • Sabine Pütter
  • Sandra Kortner
  • Sebastian Busch
  • Sebastian Muehlbauer
  • Shuxian Xiong
  • Simon Sebold
  • Simon Wegener
  • Stefan Mattauch
  • Stefano Pasini
  • Suzhe Liang
  • Theresia Heiden-Hecht
  • Thien An Pham
  • Thomas Baier
  • Thomas Keller
  • Tianfu Guan
  • Tianle Zheng
  • Tobias Chemnitz
  • Tobias Hölderle
  • Tobias Neuwirth
  • Tobias Schrader
  • Veronika Reich
  • Weimin Gan
  • Wiebke Lohstroh
  • Winfried Petry
  • Xiongzhuo Jiang
  • Yanan Li
  • Yingying Yan
  • Yishui Zhou
  • Yixi Su
  • Yuliia Tymoshenko
  • Yung Hsiang Tung
  • Yuxin Liang
  • Zakaria MAHHOUTI
  • Zerui Li
  • Zhuijun Xu
  • Zsolt Revay
    • 12:30 14:00
      Lunch 1h 30m
    • 14:00 14:05
      Plenary 1: Welcome Seminar room ground floor

      Seminar room ground floor

      Convener: Peter Müller-Buschbaum (TU München, Physik-Department, LS Funktionelle Materialien)
    • 14:05 15:00
      Plenary 1: Setting the scene Seminar room ground floor

      Seminar room ground floor

      Convener: Prof. Martin Müller (Helmholtz-Zentrum hereon GmbH)
    • 15:00 15:30
      Plenary 1: Plenary talks Seminar room ground floor

      Seminar room ground floor

      Convener: Juergen Neuhaus
      • 15:00
        Robotics 15m
        Speaker: Michael Hofmann
      • 15:15
        Embracing Digitalization for Neutron Science 15m

        In recent years, the scientific community has witnessed an exponential growth in digitalization, presenting unprecedented opportunities for advancements in neutron science. This abstract aims to highlight the importance of embracing digitalization and incorporating cutting-edge technologies, specifically focusing on the utilization of artificial intelligence (AI) and other emerging "hot topics."

        Neutron science plays a crucial role in various research areas, including materials science, chemistry, and biology. However, traditional methods for data analysis and interpretation often struggle to keep pace with the rapidly expanding volumes of data generated by modern neutron experiments. By integrating AI techniques into neutron science, researchers can unlock the potential to extract meaningful insights from vast datasets, accelerating scientific discoveries.

        This talk will explore the application of AI in neutron science. Additionally, we will introduce other "hot topics" in digitalization, including data analytics, cloud computing, and high-performance computing, which can significantly enhance the efficiency and effectiveness of neutron research.

        By embracing these digitalization strategies, researchers can overcome challenges, streamline workflows, and improve the accuracy and reproducibility of neutron experiments. Furthermore, we will discuss future trends and potential collaborations that can help advance the field of neutron science through digitalization.

        Join us for an engaging discussion that will inspire attendees to adopt AI and other digitalization techniques, fostering innovation and opening new frontiers in neutron science.

        Note: Title and abstract of this contribution were created by ChatGPT 3.5 (May 12 Version) and slightly edited by the author. Prompt: "Write an abstract of roughly 200 words for a scientific conference. The topic is 'digitalization for neutron science' and the talk will try to encourage the attendees to make more use of artificial intelligence and other 'hot topics' in digitalization."

        Speaker: Dr Sebastian Busch (GEMS at MLZ, Helmholtz-Zentrum Hereon, Germany)
    • 15:30 16:00
      Plenary 1: Post Doc Short talks Seminar room ground floor

      Seminar room ground floor

      Convener: Robert Georgii
      • 15:30
        Hydrogen in thin films: in situ studies 5m
        Speaker: Laura Guasco
      • 15:35
        Thermal moderator-reflector design of the 24Hz target station for the High Brilliance Neutron Source 5m
        Speaker: Junyang Chen (Forschungszentrum Jülich GmbH)
      • 15:40
        Coupling between phonons and crystal field excitations. Old physics, new models 5m
        Speaker: Michal Stekiel (Juelich Centre for Neutron Science)
      • 15:45
        Interdiffusion of polymers and water in colloids 5m
        Speaker: Debasish Saha (FZ Juelich)
    • 16:00 16:30
      Coffe 30m Basement

      Basement

    • 16:30 18:30
      Parallel 1: Internal Meeting E13 / E13a Seminar room basement

      Seminar room basement

      Conveners: Christine Papadakis (Technische Universität München, Physik-Department, Fachgebiet Physik weicher Materie), Peter Müller-Buschbaum (TU München, Physik-Department, LS Funktionelle Materialien)
    • 16:30 18:00
      Parallel 1: Magnetism Seminar room roof

      Seminar room roof

      Convener: Johanna K. Jochum
      • 16:30
        Non-trivial Spin Structures And Multiferroic Properties Of The DMI-Compound Ba2CuGe2O7 15m

        Incommensurate spiral magnets have raised tremendous interest in recent years, mainly motivated by their wealth of spin structures with potential non-trivial topology, such as skyrmions. A second field of interest is multiferroicity: Helical spin structures are in general ferroelectric[1], enabling the coupling of the electric and magnetic properties. Both fields present enormous potential for future devices, where spin and charge degrees of freedom are coupled. Antiferromagnetic Ba2CuGe2O7, characterised by a quasi-2D structure with Dzyaloshinskii-Moriya interactions (DMI), is a material that is interesting in both of these regards and combines them with a third one: a variety of unconventional magnetic phase transitions. Ba2CuGe2O7 is an insulator characterized by a tetragonal, non-centrosymmetric space group (P-421m) with lattice parameters a = 8.466 Å and c = 5.445 Å. The main features of the magnetic structure are due to the Cu2+ ions in a square arrangement in the tetragonal (a,b) plane with dominant nearest-neighbor AF exchange along the diagonal in the (a,b) plane and much weaker FM exchange between planes, leading to a quasi-2D behaviour. Below the Néel temperature TN = 3.05K, the DMI term is responsible for a long-range incommensurate, almost AF cycloidal spin spiral with the spins (almost) confined in the (1,-1,0) plane in the ground state[2,3].
        Our research is concentrated on two central aspects: At zero external field, neutron diffraction is used for a careful examination of the distribution of critical fluctuations in reciprocal space, associated with the paramagnetic to helimagnetic transition of Ba2CuGe2O7. Caused by the reduced dimensionality of Ba2CuGe2O7, a crossover from incommensurate antiferromagnetic fluctuations to 2D antiferromagnetic Heisenberg fluctuations is observed, highlighting the rich cornucopia of magnetic phase transitions in spiral magnetic textures. Recently, a new phase with a vortex-antivortex magnetic structure has been theoretically described[4]. It has been experimentally confirmed in a pocket in the phase diagram at around 2.4K and an external field along the crystalline c-axis of around 2.2T. A lack of evidence for a thermodynamic phase transition towards the paramagnet in high resolution specific heat measurements and a finite linewidth in energy and momentum of the incommensurate peaks in neutron scattering, as opposed to the cycloidal ground state, seem to mark the vortex phase as a slowly fluctuating structure at the verge of ordering. Experiments including electrical field in order to investigate its interplay with an external magnetic field are already planned and will allow for further pinning down multiferroic properties of Ba2CuGe2O7 [5].
        [1] M. Mostovoy. Phys. Rev. Lett., 96:1–4, 2006.
        [2] S. Mühlbauer et al, Rev. Mod. Phys, 91, 015004 (2019)
        [3] A. Zheludev, et al. Phys. Rev. B, 54 (21):15163- 15170, (1996).
        [4] B. Wolba. PhD thesis, KIT, 2021.
        [5] H. Murakawa et al. Phys. Rev. Lett., 103(14):2–5,2009.

        Speaker: Peter Wild
      • 16:45
        Complex magnetic orders and the emergent topological Hall effect in the kagome metal ErMn6Sn6 15m

        Following the discovery of a quantum-limit magnetic Chern phase in
        TbMn6Sn6, the magnetic topological metal series RMn6Sn6 (R=Gd-
        Yb, and Y, Lu, etc.), that possesses an ideal kagome lattice of Mn, has
        emerged as a new platform to explore exotic states and novel functionalities.
        We have recently carried out the growth of high-quality single
        crystals of the magnetic kagome metal ErMn6Sn6, and the physical
        properties characterizations via the magnetic susceptibility, heat capacity,
        and Hall conductivity measurements. We have also undertaken
        comprehensive neutron diffraction experiments on both single-crystal
        and powder samples at the WISH diffractometer at ISIS. Our study has
        clearly hinted a fascinating interplay between topologically non-trivial
        electronic band structures, magnetism and electronic correlations in
        ErMn6Sn6.

        Speakers: Mr Yishui Zhou (JCNS-MLZ, Forschungszentrum Jülich GmbH, Garching, Germany), Dr Yixi Su (JCNS-MLZ, Forschungszentrum Jülich GmbH, Garching, Germany)
      • 17:00
        Quench protection of high temperature superconducting magnet using metal-insulation technology 15m

        Magnets based on high temperature superconductor (HTS) provides an extreme sample environment to provide a magnetic field to detect weaker, often diffuse signals of (quantum) disordered systems. Therefore, studying HTS magnet behavior and quench properties is an essential aspect of neutron research instrumentation. In this project, we are using metal -insulation co-winding technology, where coating a superconductor with conducting over nonconducting layer has the ability to bypass the current through resistive regions reacting to reduce the risk of quench damage. This could be one of the methods to protect the magnets from possible overheating or overvoltage conditions. In this project, we are constructing a small demonstrator HTS metal-insulated coil to study the quench behavior experimentally. For initial designing a coil, we are using finite element method (FEM) simulations to calculate magnetic fields, the magnetic forces, and the thermal management study. The demonstrator HTS coil to be tested in a standard FRM-II CCR cryostat with 80mm sample tube.

        Speaker: Madhu Ghanathe (Postdoctoral researcher)
      • 17:15
        X-ray diffraction on the charge-density wave in the kagome superconductor RbV3Sb5 15m

        The newly discovered kagome superconductors AV3Sb5 (A=K, Rb or Cs), in which non-trivial band topology, charge-density wave (CDW), and superconductivity are intertwined, have attracted tremendous interests. Despite extensive recent investigations via X-ray diffraction and other complementary local probe techniques such as STM, NMR and muon spectroscopy etc., it remains a major challenge to gain a consistent picture about the CDW superstructure modulation wavevectors across different AV3Sb5 samples. For instance, it is rather controversial even only for CsV3Sb5 that distinct superstructure reflections in 2x2x2, or 2x2x4, or 1x1x4 types were actually observed below TCDW experimentally. The intriguing CDW fluctuations above TCDW was also found, and further clarifications are still needed. In this talk, we will present our recent single-crystal X-ray diffraction investigations, based on both in-house and synchrotron radiation facilities, of the CDW modulations over a wide temperature range in the less-studied RbV3Sb5. A unique CDW modulation of the 2x2x2 type can be confirmed for RbV3Sb5 below TCDW = 102 K, and no evidence for CDW fluctuations above TCDW could be found. Our detailed temperature dependence measurements of the CDW superstructure reflections indicate a second-order phase transition with a 2D Ising character. A comparison to other AV3Sb5 compounds and possible implications on the understanding of the nature of the CDW in these kagome superconductors will be given.

        Speaker: Sabreen Hammouda (Forschungszentrum Juelich/ JCNS-4@MLZ)
      • 17:30
        Magnetic, electric and toroidal polarization modes describing the physical properties of crystals 15m

        The symmetry of multiple magnetic phenomena, e.g. ferromagnetism, collinear ordering, spin reorientation, or canted antiferromagnetism, do not depend on the atomic positions. They depend only on the set of directions of magnetic moments, which we will call magnetic mode. We will present the complete classification of magnetic modes [1] based on the magnetic point groups used in two contexts: (i) the magnetic point group of the magnetic crystal class and (ii) the magnetic site symmetry point group of the Wyckoff position of interest. This classification gives restrictions to all previously mentioned phenomena [1,2]. Permutations of space inversion, $\bar{1}$, time inversion, $1’$, and space-and-time inversion, $\bar{1}’$ allow to extend magnetic modes classification to the electric, and toroidal polarisation modes classification [3]. To highlight magnetic, electric and toroidal polarisation modes new notation of magnetic point groups was introduced [3].
        Conclusion from classifications of magnetic, electric and toroidal polarisation modes is that there are multiple materials which crystal symmetry disagree with phenomena experimentally observed inside them. This gives strong motivation to re-examine their crystal structure. For instance most of the rare-earth orthoferrites, RFeO$_3$, show spin reorientation transition, e.g. $Pb’n’m (\Gamma_4) \rightarrow Pbn’m’ (\Gamma_2)$ for R = Nd, Sm, Tb, Ho, Er, Tm, Yb and $Pb’n’m (\Gamma_4) \rightarrow Pbnm (\Gamma_1)$ for R = Dy, Ce. General conclusion from the continuous magnetic modes’ classification is that spin reorientation is not possible within orthorhombic symmetry. The predicted monoclinic NdFeO$_3$ symmetry [1, 3] leads to a nontrivial Dirac multipoles motif which could be confirmed using neutron diffraction or resonant x-ray diffraction [4].
        [1] Fabrykiewicz P., Przeniosło R. & Sosnowska I. (2021). Acta Cryst. A, 77, 327.
        [2] Przeniosło R., Fabrykiewicz P. & Sosnowska I. (2018). Acta Cryst. A, 74, 705.
        [3] Fabrykiewicz P., Przeniosło R. & Sosnowska I. (2023). Acta Cryst. A, 79, 80.
        [4] Lovesey S. W. (2023). arXiv:2301.10189 [cond-mat.str-el].

        Speaker: Piotr Fabrykiewicz (Institute of Crystallography, RWTH Aachen University, Germany and Jülich Centre for Neutron Science (JCNS) at Heinz Maier-Leibnitz Zentrum (MLZ), Garching, Germany)
      • 17:45
        Meeting challenges in the time of neutron shortage: Using complementary experimental techniques for magnetism research at the large-scale facilities 15m

        The science community faces a challenging situation to maintain sustainable research with neutron methods at the moment. While neutron scattering is an indispensable microscopic probe for the investigations of magnetic order and spin excitations, there are complementary techniques at the large-scale facilities that are also suitable for magnetism research, such as element-specific magnetic resonant X-ray scattering at the synchrotron radiation facilities, and muon spectroscopy at the muon facilities. in this short talk, I will give an overview about our recent activities at the DNS group as well as the experience and lessons in the studies of topological and frustrated quantum magnets using these complementary experimental techniques at various synchrotron radiation and muon facilities in the world, with the emphasis on their unique strengths as well as their complementarities to neutron scattering.

        Speaker: Dr Yixi Su (JCNS-MLZ)
    • 16:30 18:00
      Parallel 1: Robotics/Digitalization Seminar room ground floor

      Seminar room ground floor

      Convener: Michael Hofmann
      • 16:30
        Contribution of Instrument control to higher throughput at instruments 20m Seminar room ground floor

        Seminar room ground floor

        The beam time at each of the MLZ instruments is limited.
        Therefore we should look around for ways to increase the
        proposals running at the instruments or measure more
        samples during a measurement session or perform more
        scans in the same time.

        All solution require a higher automation of the measurement
        process. The goal has to be, give the users more
        (even preliminary) results in shorter times.

        Speaker: Jens Krueger
      • 16:50
        Short presentation of ongoing robotics projects at MLZ + Discussion 1h 10m
        Speakers: Adrian Losko (Technische Universität München, Forschungs-Neutronenquelle MLZ (FRMII)), Aurel Radulescu (Forschungszentrum Jülich GmbH, Jülich Centre for Neutron Science at MLZ), Christoph Hauf
    • 18:30 19:30
      Dinner 1h Basement

      Basement

    • 19:30 20:30
      Science Slam Large seminar room

      Large seminar room

    • 09:00 09:30
      Plenary 2: Particle physics Seminar room ground floor

      Seminar room ground floor

      Convener: Bastian Märkisch (Physik-Department, TUM)
      • 09:00
        Particle physics 30m
    • 09:30 10:30
      Parallel 2: Data Management Seminar room ground floor

      Seminar room ground floor

      Convener: Wiebke Lohstroh
      • 09:30
        Data management as MLZ - future perspectives 15m Seminar room ground floor

        Seminar room ground floor

        This contribution will give a short overview on the plans for data management at MLZ - i.e. the workflow from proposal, epxeriment, storage, visualisation to analysis and publication. This contribution is thought as brief introduction to the further discussion on requirements from the instrument scientists perspective.

        Speaker: Wiebke Lohstroh
      • 09:45
        Activities of the Data-Driven Discovery Group on Data Reduction for MLZ Instruments 15m Seminar room ground floor

        Seminar room ground floor

        Data reduction is a transformation of a dataset collected during a scattering experiment into a dataset in physical units. It requires detailed knowledge of geometry and configuration of the instrument at which the dataset was collected. As a result, data reduction is an essential stage required for linking raw experimental data to a meaningful scientific publication. As such, development of automated and user-friendly data reduction workflows for MLZ instruments is among main foci of the Data-Driven Discovery group. In my talk, I will discuss our recent activities in this context, including: a) development of graphical user interfaces for the DNS and POWTEX instruments, b) integration of the data reduction workflow for SANS-1 into the popular Mantid [1] framework, c) inclusion of multiple scattering into analysis of polarized neutron diffraction data.

        [1] O. Arnold, et al., Nucl. Instrum. Methods Phys. Res. A, 764, pp. 156-166 (2014).

        Speaker: Oleksandr Koshchii
      • 10:00
        Development of in-situ techniques for neutron scattering instruments or: How to mitigate the negative effects of (future) reactor shutdown periods at MLZ. 15m Seminar room ground floor

        Seminar room ground floor

        Let us face it: The research reactor FRM II will experience future shutdown periods of 6 months or longer also in the near and far future be it due to regulatory issues with the local government or be it due to technical problems encountered. In this contribution I would like to show how to mitigate the negative effects of these shutdown periods and to turn them into something productive and positive for the whole MLZ.
        First, I will dwell upon the recent developments of in-situ techniques at neutron scattering instruments which were performed at the MLZ. I will also summarize the new sample environment options developed, as far as I have learned about them. The latter lists will not be complete, since I do not aim to demonstrate what we have done in the past, but I would rather look into the future: What can we do and develop together with user groups in the future using the time and staff available due to the (future) reactor shutdown periods.
        I will also quickly summarize the new facilities in the surrounding labs made available for users recently.
        To transfer these efforts to politicians and research budget holders I suggest to bundle the above mentioned activities and to give them a common name and web-page design visible to outside users and scientists even at the early stage of a first drawing or idea. This might enable more user groups to join the efforts on site and it might open up routes to write common grant proposals. Especially in light of the up-coming sources, the European Spallation Neutron Source (ESS) in Lund or a high brilliant neutron source (HBS) in Jülich, one should position the MLZ as a knowledge base for not only neutron instrumentation, but also sample environment and in-situ techniques.
        In the past, the Helmholtz Zentrum Berlin has demonstrated a similar concept with great success despite being a neutron source with a somewhat smaller reactor power.

        Speaker: Tobias Schrader
      • 10:15
        Discussion 15m
    • 09:30 10:30
      Parallel 2: New Components Seminar room roof

      Seminar room roof

      Convener: Dr Peter Link
      • 09:30
        Additive manufacturing of custom neutron shielding solutions 15m

        Together with ColorFabb we developed a 3D printable shielding material based on PLA and hexagonal boron nitride, allowing to easily manufacture complex shielding geometries, even with hobby-grade 3D printers. While using the material we have seen considerable interest internally, as well as from external collaboraters, and gained experience in designing and printing custom shielding solutions. Hence, we would like to share our experience in working with the material and discuss further developments.

        Speaker: Tobias Neuwirth
      • 09:45
        Monte-Carlo simulations of the new radiation shielding at the thermal beamport SR8 @ FRM II with SERPENT 2 15m

        The thermal beamport SR8 at the research neutron source Heinz Maier-Leibnitz in Garching will be optimized to allow the simultaneous operation of three independent monochromatic powder diffractometers. SPODI will continue to be one of the world-leading high-resolution powder diffractometers. FIREPOD will be a dedicated high throughput instrument, well suited for a broad range of fast parametric studies. ERWIN will be a highly versatile multi purpose diffractometer for both powder as well as single crystals. Due to the unique characteristics of each instrument, the optimized beamport SR8 will be able to cater for a wide range of experimental demands and will substantially increase available beam time for neutron powder diffraction. To exploit the full capabilities of each instrument a complete rebuilt of the primary neutron optics at the beamport SR8 is necessary. This requires an entirely new radiation shielding around the neutron guides and monochromators.

        In this contribution, the results from detailed Monte-Carlo simulations to optimize the biological SR8-shielding are presented. Employing the SERPENT2 code, the full radiation transport of neutrons, as well as gamma radiation through the different shielding materials is simulated. While taking boundary conditions such as available space, floor load and costs into consideration, the underlying detailed CAD-based model is iteratively optimized to achieve a total dose rate lower than the desired limit of 3µSv/h outside the shielding.

        Speaker: Christoph Hauf
      • 10:00
        Development of a Nested Mirror Optic Array for the Thermal TAS PUMA at MLZ 15m

        A persistent challenge for the inelastic neutron scattering technique has been the low scattering cross-section of neutrons, necessitating large sample sizes compared to elastic neutron scattering or inelastic x-ray scattering. Focusing the neutron beam is a viable technique to increase the flux reaching the sample, but previous techniques suffer from limitations to beam size, beam quality or an excessively close distance to the sample which interferes with sample environments. The nested mirror optic (NMO) is an ideal solution in many ways to overcome these challenges and provide a small, well-behaved beam at the sample position while keeping the optical components a reasonable distance to make room for the sample environment equipment. An ongoing project has led to the development of an NMO prototype for the cold triple-axis spectrometer (TAS) MIRA at MLZ, but with a limited energy transfer range. The development of supermirror coatings with large m-values has opened up the possibility to apply this technique to the thermal TAS instrument PUMA at MLZ. While current focusing techniques on PUMA yield a cross section of 20mm x 20mm, the current NMO project seeks to develop, install and commission an NMO setup that will reduce the beam size to 5 mm x 5 mm while preserving 50% of the incoming neutrons, for an 8-fold increase in flux on small samples. It will do this while also providing space for the sample environment and preserving the beam characteristics, and will be straightforward to mount and dismount to adjust for the needs of each user. I will discuss the planned setup and our current progress in designing the NMO setup for PUMA, as well as the scientific case for such a device with several planned use cases.

        Speaker: Dr Adrian Merritt (Karlsruher Institut für Technologie)
      • 10:15
        HYMN – A novel unified toolbox for in-situ magnetic hyperthermia experiments using neutron scattering 15m

        One of the most promising use cases of magnetic hyperthermia, is the use of magnetic nanoparticles (MNPs) for cancer therapy. In this treatment, MNPs are immersed into tumours and by heating with external magnetic fields, typically 100-900 kHz, destroy cancer cells. Since it is a clinical application the optimization of field parameters and in turn, the heating power, is crucial to maintain both safety and high efficiency. Safety dictates an upper limit of applied magnetic field exists. Hence, for successful application, the heating power needs to be improved by the optimization of MNPs structure. What is more, recent studies have shown a huge increase in magnetic heating by the excitation of transversal spin modes in MNPs, in low GHz range. An ideal tool for the characterization of such MNPs is small angle neutron scattering (SANS), with the extended functionality provided by the MIEZE technique. The aim of our ERUM-Pro HYMN project is to develop a novel, unified experimental and computational toolbox for in-situ magnetic hyperthermia experiments under clinical conditions, utilising the SANS and MIEZE-SANS technique, combined with nanomagnetic simulations. This will be achieved by the development of two custom-made setups for operation in the 100-450 kHz (up to 30 mT) as well as 0.5-4 GHz (up to 2 mT) range. We present first SANS results, where we used in-situ RF heating at 450 kHz to examine the dynamic structure formation of magnetite nanocubes with 12, 34 and 53 nm size.

        Speaker: Michal Dembski-Villalta
    • 10:30 11:00
      Coffee 30m Basement

      Basement

    • 11:00 13:00
      Parallel 3: Internal Post Doc meeting Seminar room roof

      Seminar room roof

    • 11:00 13:00
      Parallel 3: Internal meeting E13 / E13a Seminar room basement

      Seminar room basement

      Conveners: Christine Papadakis (Technische Universität München, Physik-Department, Fachgebiet Physik weicher Materie), Peter Müller-Buschbaum (TU München, Physik-Department, LS Funktionelle Materialien)
    • 11:00 13:00
      Parallel 3: Sample Environment Road Map
      Convener: Michael Schulz
      • 11:00
        Preparation of a CaBER Sample Environment and Microfluidic Devices for In-Situ Scattering Measures of Polymer Solutions in Extensional Flow 15m

        Microfluidic flows using hyperbolic contractions and capillary break-up extensional rheometery (CaBER) have emerged as key techniques to characterize polymer solutions experiencing uniaxial extensional flow [1,2]. In this work, two approaches are presented to explore the microstructural evolution during extensional flows and relate those features in situ to the macroscopic properties exhibited by polymer solutions during extension. A CaBER sample environment has been prepared for use at small angle scattering (SAS) beamlines to conduct simultaneous CaBER-SAS experiments by configuring the instrument such that the beamline, linear motor, and high-speed camera are perpendicular to one another. An essential feature of the setup is a novel geometry and sample cell to allow for repeated testing of a single polymer solution sample by limiting effects such as solvent evaporation and inconsistent (re)loading conditions. As a second approach a multi-channel microfluidic device has been prepared. The channel profiles resemble hyperbolic contractions and have been manufactured through selective laser etching by. To allow for microstructural characterization in situ the channels within the microfluidic device have been arranged in a 2D array, increasing the overall effective volume of material within the device, and ensuring sufficient signal in a SANS environment. Solutions of 35 kDa and 8 MDa PEO in water with concentrations in the dilute and semi-dilute regimes have been tested in both devices to determine the setup’s efficiencies during repeated testing in the CaBER environment as well as to characterize the flow profile within the stacked microfluidic device.
        References:
        [1] S. L. Anna, et al., J. Non-Newtonian Fluid Mech., 87, 2 (1999)
        [2] T. J. Ober, et al., Rheol Acta, 52 (2013)

        Speaker: Matthew Wade (Juelich Center for Neutron Science)
      • 11:15
        Status of the On-Site High Pressure Diffraction Option on Single Crystals at MLZ 15m

        The neutron single crystal diffractometer HEiDi uses the hot source of FRM II to offer high flux down to short wavelengths. Its large $q$ range and flexibility concerning experiments between 2.5 K and 1300 K make it a versatile tool for detailed studies on structures for many topics in physics, chemistry and mineralogy.
        In two consecutive BMBF-funded projects from 2016 to 2022 (05K16PA3, 05K19PA2), the application suite of HEiDi (and its polarized twin POLI) was extended to enable high-pressure (HP) experiments, firstly with diamond anvil cells [1, 2] and recently by introducing clamp cells for larger sample volumes [3]. These cells can also be used on DNS and MIRA to perform comprehensive experiments on shared samples/PCs.
        This overview presents the status of the various new HP cells and their possible applications as well as some related technical developments in neutron optics at HEiDi, for instance a new 2D PSD currently under construction. These extensions will increase the instruments performance not only for HP experiments and thus open up further applications as well.

        [1] A. Eich et al.; Magnetocaloric Mn$_5$Si$_3$ and MnFe$_4$Si$_3$ at variable pressure and temperature; Mater. Res. Express 6, 096118 (2019).

        [2] A. Grzechnik et al.; Combined X-ray and neutron single-crystal diffraction in diamond anvil cells; J. Appl. Cryst. 53(1), 1 - 6 (2020).

        [3] A. Eich et al.; Clamp cells for high pressure neutron scattering at low temperatures and high magnetic fields at Heinz Maier-Leibnitz Zentrum (MLZ); High Press. Res., 41[1], 88–96.

        Speaker: Robert Georgii
      • 11:30
        New laser furnace for the STRESS-SPEC instrument 15m

        Current topics in materials research such as new production processes, e.g. additive manufacturing (AM), or sustainable energy research, e.g. high-temperature alloys, require a highly flexible sample positioning system during diffraction experiments. Therefore, the STRESS-SPEC group has pioneered the use of industrial robots for sample handling and positioning at neutron diffractometers [1, 2]. To fully exploit the capabilities of the robotic positioning system, a dedicated sample environment is essential. In this talk, we will present a recently developed lightweight laser furnace with a large neutron acceptance angle, which allows the investigation of samples at elevated temperatures up to 1100 °C, while benefiting from the positioning flexibility of a 6-axis industrial robot. The furnace control rack was built with interoperability in mind, allowing to control various other sample environment devices as well. Some features and example use cases of the laser furnace will be presented.
        Furthermore, we will also give an outlook at the future development of a lightweight mechanical tensile testing machine that can also be mounted on a 6-axis industrial robot.

        [1] H.-G. Brokmeier et al., Mater. Sci. For. 652 (2010) pp. 197–201. DOI: 10.4028/www.scientific.net/MSF.652.197
        [2] C. Randau et al., Nucl. Instr. Meth. A 794 (2015) pp. 67–75. DOI: 10.1016/j.nima.2015.05.014

        Speaker: Lijiu Wang
      • 11:45
        Discussion 1h 15m
    • 13:00 14:30
      Lunch 1h 30m Basement

      Basement

    • 14:30 15:00
      Plenary 3: Magnetism
      • 14:30
        Magnetic Neutron Scattering – From basic scattering theory to cutting edge applications 30m

        Since their inception, neutron scattering methods have significantly contributed to many advancements in solid state research. This is especially true for the study of magnetic materials, where neutrons provide a uniquely qualified probe to investigate magnetism on the microscopic scale. This talk aims to elucidate the relation between the magnetic properties of a sample and the observable neutron scattering cross sections. Contemporary examples, will be used to connect the basic theory with real world measurement data acquired at a variety of instruments like small angle scattering, single crystal and powder diffraction, three-axis spectroscopy as well as neutron imaging. Finally, a deeper dive into low-dimensional magnetism in metal-organic compounds will showcase the connection of solid state magnetism and sought-after phenomena such as quantum criticality and high temperature superconductivity. This will highlight the importance of magnetic neutron scattering in condensed matter physics and material science.

        Speaker: Dr Lukas Beddrich (Heinz Maier-Leibnitz Zentrum (MLZ))
    • 15:00 15:30
      Plenary 3: Short Talks Posdocs Seminar room ground floor

      Seminar room ground floor

      • 15:00
        Hydrogenation change magnetism in nm thin film 5m
        Speaker: Po-Chun Chang (Forschungszentrum Juelich/ JCNS-4@MLZ)
      • 15:05
        Unknown structure solving and its further application combined with the theoretical simulation 5m
        Speaker: Yung Hsiang Tung (Forschungszentrum Juelich JCNS-4)
      • 15:10
        Neutron imaging at MLZ 5m
        Speaker: Richi Kumar
      • 15:15
        Physics Lab 5m Seminar room ground floor

        Seminar room ground floor

        Speaker: Bastian Veltel (TUM FRM II)
    • 15:30 16:00
      Plenary 3: Proposal system Seminar room ground floor

      Seminar room ground floor

      Convener: Dr Ina Lommatzsch (Jülich Centre for Neutron Science JCNS at Heinz Maier-Leibnitz Zentrum (MLZ), Forschungszentrum Jülich)
    • 16:00 16:45
      Plenary 3: Podium discussion: Results from Robotics, Data Management, Sample Environment and New Methods Seminar room ground floor

      Seminar room ground floor

    • 17:00 18:30
      Walk to the Riessersee
    • 18:30 22:00
      Dinner at Hotel Rissersee Riessersee Hotel, Riess 5 D-82467 Garmisch-Partenkirchen

      Riessersee Hotel, Riess 5 D-82467 Garmisch-Partenkirchen

    • 22:00 22:20
      Bus transport back to Seminarhaus Grainau
    • 09:00 10:30
      Parallel 4: Detectors Seminar room ground floor

      Seminar room ground floor

      Convener: Wiebke Lohstroh
      • 09:00
        Current neutron detection techniques for neutron scattering applications - Overview and perspectives 30m

        The advent of the new spallation sources as well as the various major upgrade programmes of existing facilities have given great impetus to the new and further development of neutron detection techniques for neutron scattering applications in the last decade. Great progress has been made, particularly in the area of count rate capability and large detection areas.
        With regard to the projects planned as part of the MORIS program, this presentation is intended to give an overview of the current technologies, their performance, strengths and weaknesses and perspectives

        Speaker: Karl Zeitelhack (MLZ)
      • 09:30
        Recent instrument development and plan on POLI 15m

        The single crystal diffractometer POLI is dedicated to diffraction using polarized neutrons and can additionally host bulky sample environments. Currently, three standard setups are implemented on POLI: zero-field spherical neutron polarimetry, flipping ratio method with high magnetic fields and non-polarized diffraction under various special conditions. Here we reported our recently instrument developments, including an 8T magnet with very low stray fields, a supermirror bender polarizer, SEOP polarizer and analyzer, piezo-driven slits and new incident wavelengths. We will also present our detector upgrade plan related to the BIDIM detector from LLB and the proposal in the MORIS program.

        Speaker: Jianhui Xu (MLZ, TUM)
      • 09:45
        Event Mode Neutron Imaging Detectors 15m

        Event mode neutron imaging detectors generate information for every neutron hitting the detector individually. This allows the usage of algorithms to analyze the individual events and improveme noise supression as well as temporal and spatial resolution. The detector have already been tested sucessfully for fast, thermal and cold (ToF) imaging, and neutron diffraction.

        Speaker: Alexander Wolfertz (TUM FRM2)
      • 10:00
        Event-based neutron radiography with Image Intensifier and CMOS camera 15m

        High-resolution neutron radiography requires an imaging system capable of detecting the exact location of the absorbed neutrons in the scintillator screen. This is realized by a sensitive CMOS camera with high frame rate capabilities and an image intensifier, which is able to amplify the weak light output created by individually absorbed neutrons. Identifying and recording single neutron events appearing as a cluster of intensity spots allows narrowing the point spread function of the imaging system compared to conventional intensity-integrated detection mechanisms. Further, it facilitates the characterization and optimization of the scintillator properties for better imaging performance.

        Speaker: Alex Gustschin (Neutron Imaging / ANTARES)
      • 10:15
        Diskussion 15m
    • 09:00 10:50
      Parallel 4: Material Science 1 Seminar room roof

      Seminar room roof

      Convener: Ralph Gilles
      • 09:00
        Electrodepositing lithiophilic nanoparticles as artificial interphase for anode-free lithium ion batteries 15m

        Anode free batteries are designed to significantly decreases the weight of a cell.They necessitate immaculate reversibility of the charge
        and discharge process, as no further lithium other than the amount loaded into the cathode is available. Homogeneous plating and
        stripping of lithium onto a current collector is not readily achieved when plating on e.g. on copper. Lithiophilic metals like Au and Zn
        can be used to engineer the surface of a current collector, for example through the application of a thin sputtered film (50 nm), with
        which the lithium forms metallic interphases and hence drastically changes the plating environment. This can be explored further through
        the electrodeposition of said metals, which can be generated with different size and number density and therefore provide a variety of
        plating substrate configuration. Correlating morphology and arrangement of the particles to their electrochemical behaviour in lithium half cells should elucidate their effect on the anode interphase and allow for precise decoration of the current collector for improved batteries.

        Speaker: Gilles Moehl (ADVMAT)
      • 09:15
        Thermal and structural behavior of graphite battery anodes 15m

        High-performance graphite evolved to the most common anode material and is used in nearly every commercial Li-ion battery nowadays. However, there is a clear lack of information about the structural stability of Li$_{x}$C$_{6}$ and its phase diagram. In literature, temperature-resolved phase stability of lithiated graphites is therefore studied poorly and the results are often controversial. Hence, the structural evolution of lithiated graphites was studied at high temperatures showing the decomposition of the lithiated anode and a corresponding loss of intercalated lithium ions, resulting in the evolution of phases like LiF and Li$_{2}$O, which are strongly correlated with the degradation of the solid electrolyte interface (SEI).

        Speaker: Tobias Hölderle
      • 09:30
        A new type of redshift - investigation of CsCaHxF3−x:Eu2+ 15m

        The heteroanionic approach for the design of materials has led to variety of novel systems with unique properties. In particular, heteroanionic hydrides emerged with promising properties themselves. Over the recent years such compounds, in particular hydride fluorides have been thoroughly investigated as potential host materials for rare earth activated luminescence.
        Here, the solid-solution CsCaHxF3−x:Eu2+ is presented as the first calcium containing system of this kind. Investigations of the solid-solution’s properties reveals unique optical behaviour: by increasing the hydride content within the series, a completely new type of redshift is observed upon excitation with UV-light. Instead of a single red-shifting emission band, new narrow emission bands emerge at the low energy regions. In total, the ratios of these emission bands determine the observable emission colour. Such a redshift mechanism has not been reported for any related system.
        For the elucidation of this behaviour, a variety of analytical methods were applied. With the help of neutron diffraction data, obtained at the SPODI@MLZ, in combination with X-ray diffraction data, the crystal structures were fully solved. Further analytical techniques such as luminescence spectroscopy and vibrational spectroscopy then allow for the full understanding of this unique behaviour which will be explained in detail herein.
        These findings will help for the design for new efficient phosphors, especially useful for red-emitting pc-LEDs.

        Speaker: Dr Alexander Mutschke
      • 09:45
        Structure evolution in LNMO, a novel cathode material for Li-ion batteries 15m

        High voltage spinel LNMO is one of the most promising next-generation cobalt-free cathode materials for Li-ion batteries. Besides the typical compositional range of LixNi0.5Mn1.5O4 (0 < x < 1) in the voltage window 4.90 to 3.00 V, additional Li can be introduced into the structure in an extended voltage range to 1.50 V. Theoretically, this leads to significant increase of the specific energy from 690 to 1190 Wh/kg. However, utilization of the extended potential window leads to rapid capacity fading, voltage polarization that lack a comprehensive explanation.

        In this work, we conducted operando XRD and neutron diffraction on the ordered stoichiometric spinel LixNi0.5Mn1.5O4 within 0 < x < 2.5 in order to understand the dynamic structure evolution and correlate it with the voltage profile [1]. We were able to provide a conclusive explanation for the additional voltage step at 2.10 V, the sloping voltage profile below 1.80 V, and the additional voltage step at ~3.80 V.

        [1] Nicola M. Jobst, Neelima Paul, Premysl Beran, Marilena Mancini, Ralph Gilles,Margret Wohlfahrt-Mehrens, and Peter Axmann, J. Am. Chem. Soc. 2023, 145, 4450−4461

        Speaker: Dr Neelima Paul (Technical University of Munich, Heinz Maier-Leibnitz Zentrum (MLZ))
      • 10:00
        CGO-Cu cermets characterization by in situ scattering measurements with a dilatometer 15m

        The long-term stability of solid oxide fuel cells (SOFC), electrolyzers (SOEC) and catalytic membrane reactors is highly dependent not only on their electrochemical properties but also on the similar thermal evolution of all their constituting parts, ensuring mechanical compatibility, i.e. electrolyte and electrodes. This kind of devices have a good performance at high temperatures. However, high temperatures and thermal cycling put strain on cell constituents, and oxidation of electrodes caused by demixing of fuels and water limit both operation and lifetime. Thus, the decrease in operation temperature is needed. Most SOFCs are based on yttrium-stabilized zirconia (YSZ) electrolyte, between a porous Ni/YSZ anode and a porous lanthanum strontium manganite cathode, which operate above 800 °C. In order to decrease the operation temperature of these devices new electrolyte materials are under study. Ce$_{0.8}$Gd$_{0.2}$O$_{2-\delta}$ (CGO) is an ionic conductor capable to operate at 600-800 °C, whose performance improves by decreasing thickness. Therefore, there is a need of finding compatible anode materials with enough electronic conductivity and electrocatalytic activity that are also mechanically stable to support the thin electrolyte. Cu based ceria cermets demonstrated to be advantageous in replacing Ni-cermets for the direct oxidation of hydrocarbons since, unlike Ni-containing cermets, Cu does not promote significant carbon coking. In these cermets the electrical conductivity is warranted by Cu, whereas ceria is responsible for the catalytic activity in oxidation reactions, partially compensating the Ni catalytic activity in standard Ni-YSZ electrodes. Besides, Cu is more economically viable than Ni.
        In this study, we optimized CGO-Cu composites as anode materials for CGO electrolytes. Different samples with different ratios of CGO and Cu ranging from 40-60 to 70-30 vol.% were studied by high temperature in situ x-ray diffraction (XRD @P07 Desy) at the same time as the dilatometric signal was obtained. Differences in the micro (XRD) and macro (dilatometer) thermal expansion coefficient (TEC) due to the different ratios of the composites were correlated with the microstructure (SEM and XRD) and with the electrochemical properties, which allowed selecting best anode materials for high temperature green energy applications.

        Speaker: Cecilia Solis
      • 10:15
        Defect Studies in Tungsten using Positron Annihilation Spectroscopy 15m

        We study vacancy-type defects in tungsten mono-crystals using positron annihilation Doppler-broadening and lifetime spectroscopy. These studies are part of nuclear fusion research necessary to predict the durability of reactor walls.

        Speaker: Mr Vassily Vadimovitch Burwitz (MLZ)
    • 09:00 10:30
      Parallel 4: Soft Matter 1 Seminar room basement

      Seminar room basement

      Convener: Henrich Frielinghaus (JCNS)
      • 09:00
        Topology correlation to nanoscale hydration of polymer brushes 15m

        By utilizing time-of-flight neutron reflectometry (ToF-NR) under different relative humidity, we demonstrate that polymer brushes constituted by hydrophilic cyclic macromolecules exhibit more compact conformation with lower roughness compared to linear brush analogues, due to the absence of dangling chain ends extending at the interface. [1] In addition, due to increased interchain steric repulsions, cyclic brushes feature larger swelling ratio and increased solvent uptake with respect to their linear counterparts presenting the same composition and comparable molar mass. Moreover, the two topologies exhibit differences in ageing, upon repetitive cycling/drying trials.
        To correlate the equilibrium swelling ratios as a function of relative humidity for different topologies a new form of the Flory-like expression for equilibrium thicknesses is proposed. The relative humidity represents the chemical potential balance between brush and surrounding environment. The Flory-like expression, which has been utilized so far for thin polymer films, breaks down for the cyclic brush. Additional topological contributions need to be taken into account in this expression, in order to rationalize differences reflected in swelling ratios and solvent content between the linear and cyclic polymer brush topologies.

        [1] Vagias, A., Nelson, A., Wang, P., Reitenbach, J., Geiger, C., Kreuzer, L. P., Saerbeck, T., Cubitt, R., Benetti, E. M., Müller-Buschbaum, P., The Topology of Polymer Brushes Determines Their Nanoscale Hydration. Macromol. Rapid Commun. 2023, 2300035

        Speaker: Apostolos Vagias (FRM2 / TUM)
      • 09:15
        Diffusion of water in waterborne polymer colloid films containing different hydrophilic shells 15m

        The waterborne latex films, obtained from the dispersions of latex particles are of particular interest due to the non-content of volatile organic compounds (VOC), which is often mandatory under environmental legislation [1]. However, abrupt water penetration inside the films restricting their lifespan and deteriorating the shining of the coating, limiting their uses [2]. In order to prepare efficient and solvent-free coatings with the low glass-transition temperature (Tg < the drying temperature) but with higher mechanical strength, we have integrated hydrophilic layers (Acrylic acid/ Poly(acrylamide)) around the hydrophobic cores (mixture of Methyl methacrylate and Mutyl acrylate) in the latex film. Polymer latex particles with different morphologies (hairy layer variants and core-shell particles) have been synthesized using emulsion polymerization. Polymer latex films have been prepared in the next step by evaporating water in a thermo- and humidistatic chamber at temperature 25 oC. The structure formation of polymer latex films in the dry state (crystallinity) and in re-swelled state (change in crystallinity and whitening or blushing) have been studied to propose a recipe for the preparation of efficient latex coatings. The combine study by small-angle neutron scattering (SANS) and small-angle X-ray scattering (SAXS) show the FCC-like structure formation by the latex film, which become more organized with the inclusion of the that the hydrophilic shell. The inclusion of hydrophilic shell also promotes the formation of the homogeneously swollen film and slows down the development of water “pockets”, preventing the deterioration of the latex film over time.
        1. T.N. Tran, E. Rawstron, E. Bourgeat-Lami, D. Montarnal, ACS Macro Lett. 7 (2018) 376.
        2. I. Konko, S. Guriyanova, V. Boyko, L. Sun, D. Liu, B. Reck, Y. Men, Langmuir. 35 (2019) 6075.

        Speaker: Debasish Saha (FZ Juelich)
      • 09:30
        Electric Field-Induced Assembly of Highly Crosslinked Ionic Microgels 15m

        The electric field driven assembly of highly crosslinked ionic microgels at effective volume fraction, ϕeff=0.04 is studied using a confocal microscope. The isotropic microgels undergo structural transitions depending on the field strength and microgel concentration. At low ϕeff, the ionic microgels interact via long-range Yukawa type interaction and the interparticle separation between microgel particles is much larger than the microgel particle diameter. Each microgel particle experiencing the field can be considered as a point dipole. These point dipoles are attracted mutually and assemble along the direction of the applied field and align to form linear chains. At a higher field strength, a gas phase co-existing with islands of a bct and ring structures are observed in the xy plane. Clusters with fewer microgels tend to form rings, whereas larger clusters arrange into bct structure. The microgels instantaneously redisperses once the electric field is turned off.

        Speaker: BRIJITTA JOSEPH BONIFACE (MLZ, FRM II)
      • 09:45
        The Study of Local and Higher Order Structure in Soft-Matter Systems by Contrast-Variation Simultaneous SANS & WANS 15m

        Materials based on semi-crystalline polymers are used in different fields of applications, from high temperature to plastics, elastomers and fibers, from biomedicine to aerospace, from oil industry to fuel cells. Such materials exhibit a phase separation in crystalline and amorphous regions. The crystalline domains are characterised by a complex morphology spanning a broad length scale from Å to hundreds of micrometres and consisting of hierarchically organised, multiple structural planes such as crystalline unit cells, lamellar crystals, fibrils or boards and fibres or spherulites. Furthermore, the amorphous regions in the bulk and between the lamellae can be functionalised, leading to even more complex morphologies when external stimuli such as humidity (RH), temperature (T) or uni-axial deformation (UD) are applied to the sample. For the structural characterisation of such complex morphologies, a large length scale has to be covered, which usually requires a combination of different experimental methods in structural analysis. Due to the advantage of contrast variation and the large Q-range that can be covered, small angle (SANS) and wide angle (WANS) neutron scattering techniques are particularly suitable for the detailed study of natural and synthetic polymeric materials. However, when working with different instruments to collect scattering data in wide and small scattering ranges, it is difficult to ensure perfect reproducibility of sample composition and quality as well as external field conditions so that a global analysis of data collected in different experimental geometries and at different times can be reliably performed. The simultaneous use of wide and small neutron scattering methods in the same experiment is therefore necessary for sensitive or expensive samples when special care must be taken with sample preparation (composition, quality, quantity, etc.) or treatment (temperature, humidity, etc.) during the experimental investigation.
        Here I report on the experimental investigation of various semi-crystalline polymer and soft-matter systems under different RH, T and UD conditions using neutrons on pinhole SANS or TOF SANS/WANS diffractometers, with emphasis on the Q range and experimental resolution involved in structural studies. The use of complementary methods (SAXS, FTIR, etc.) to better understand the local or long-range structures will also be discussed.

        Speaker: Dr Aurel Radulescu (Forschungszentrum Jülich GmbH, Jülich Centre for Neutron Science at MLZ)
      • 10:00
        Interaction of nanoparticles with lipid films: the role of symmetry and shape anisotropy 15m

        Nanoparticles are nowadays widely used in biology and have quickly emerged as essential to modern medicine. When nanomaterials come into contact with biological membrane, their interaction with biomacromolacules and biological barriers will determine their bioactivity, biological fate and cytotoxicity. It goes without saying that understanding the interaction between nanomaterial and biological interfaces is vital to bridge the gap between design/synthesis/engineering of nanoparticles and their full translation into end-use applications. In this context, the role of symmetry/shape anisotropy of both the nanomaterials and biological interfaces in their mutual interaction, is a relatively unaddressed issue.
        Here we present the findings about the interaction of gold nanoparticles (NPs) of different shape, i.e. nanospheres and nanorods, with biomimetic membranes of different symmetry, i.e. lamellar (of 2D symmetry), and cubic (of 3D symmetry) membranes.
        Through the combination of structural scattering techniques (in particular Neutron Reflectometry), we observed that, on a nanometric lengthscale, the structural stability of the membrane towards NPs is dependent on the topological characteristic of the lipid assembly and of the NPs, with higher symmetry related to higher stability. Moreover, Confocal Microscopy analyses highlight, on a micrometric lengthscale, that cubic and lamellar phases interact with NPs according to two distinct mechanisms, related to the different structures of lipid assemblies.
        This study represents a first attempt to systematically study the role of membrane symmetry on the interaction with NPs; the results will contribute to improve the fundamental knowledge on nano-bio interfaces and, more in general, will provide new insights on the biological function of lipid polymorphism in interfacial membranes as a response strategy.

        Speaker: Gaetano Mangiapia
      • 10:15
        Sassena -- a tool for validation of Molecular Dynamics simulations with neutron and X-Ray scattering experiments 15m

        Neutron and X-ray scattering experiments are powerful techniques to investigate any material at the atomic to mesoscopic level. They give us structural and dynamic information. However, it is not possible to extract the relative position, shape, and velocity of the scatterers directly from the scattering data due to the phase problem. One possibility to circumvent this problem is to simulate the materials at different length scales and to calculate scattering patterns from these simulations.
        To cover the several orders of magnitude in reciprocal space accessible by scattering techniques, a high-performance software solution is required to deal with large systems at fine resolution. For this task, several programs are available; we have chosen Sassena for our work. Sassena inherits distributed memory parallelization (MPI) from its previous version. We augmented this by vectorization and shared memory parallelization (OpenMP) to bolster the computing speed; gains of up to an order of magnitude were achieved. Furthermore, the introduction of shared memory parallelization introduces the possibility of hybrid parallelization.

        Additionally, we also added a new feature in the program that allows the removal of the coherent scattering signal caused by the finite size of the simulation box.

        Speaker: Arnab Majumdar (Helmholtz Zentrum hereon)
    • 11:30 12:00
      Walk to train station Zugspitzbahn
    • 12:00 13:00
      Train to Zugspitze
    • 13:00 14:00
      Tour Schneefernerhaus: Group 1
    • 14:00 15:30
      Tour Wetterturm
      • 14:00
        Group 2 30m
      • 14:30
        Group 3 30m
      • 15:00
        Group 4 30m
    • 16:30 17:30
      Train to Grainau
    • 18:30 20:00
      Dinner 1h 30m Basement

      Basement

    • 20:00 21:00
      Evening talk Seminar room ground floor

      Seminar room ground floor

      Convener: Robert Georgii
      • 20:00
        Revealing nature's secrets with the Higgs boson 1h Seminar room ground floor

        Seminar room ground floor

        Speaker: Sandra Kortner (Max-Planck-Institut für Physik)
    • 09:00 09:30
      Plenary 4: Soft Matter Seminar room ground floor

      Seminar room ground floor

      Convener: Stefan Mattauch (FZ-Juelich)
      • 09:00
        Towards an improved understanding of food emulsions via neutron scattering and neutron spectroscopy 30m

        The stability of food emulsions depends -beside other effects- on a complex interplay between proteins, phospholipids, oil and water. Preparing milk-based and sustainable plant-based emulsions requires good knowledge in interfacial and emulsion stabilization mechanisms, affected by the emulsion composition. To understand these mechanisms in detail different length scales from interatomic to macroscopic distances need to be investigated.
        Neutron scattering techniques provide insight into such emulsions on these length scales depending on the technique used. Combining structural information on molecular length scales from small angle x-ray and neutron scattering (SAXS and SANS) with time dependent neutron spin echo spectroscopy (NSE) allows to expand our understanding towards intermolecular interactions within the interface. These interactions are linked to the emulsion stability – the elastic properties of the protein or protein/phospholipid stabilized oil/water interface on molecular length scales. NSE provides in this combination the time dependent correlation function in reciprocal space, S(q,t), on molecular length scales and time scales in the nanosecond range relevant for thermally driven motion of mesoscopic systems such as the emulsion interfaces.
        This presentation introduces the neutron and x-ray scattering techniques which broadens the classical characterization of food emulsions. Results from emulsions stabilized with -lactoglobulin as a representative milk protein, and different plant-based proteins, are presented and discussed. Contrast variation by deuteration of some components of the emulsions is applied to focus on the interfacial region, relying on the uniqueness of neutrons.
        Connecting these emerging results with classical characterizations such as interfacial tension or viscoelasticity helps understanding the complex mechanisms of interfacial stability and may contribute to a knowledge driven development of sustainable food emulsions.

        Speaker: Theresia Heiden-Hecht (JCNS-4)
    • 09:30 10:30
      Parallel 5: Material Science 2 Seminar room ground floor

      Seminar room ground floor

      Convener: Michael Hofmann
      • 09:30
        Elasto-plastic behaviour in titanium alloys 15m

        Neutron and synchrotron diffraction studies under mechanical stress in titanium alloys Ti-64 (near α-alloy), Ti-6246 (α+β alloy), Ti-5553 (near β-alloy) and Ti-38644 (β-alloy) were performed to investigate the deformation mechanisms. In particular, the determination of single-crystalline elastic constants derived from the measured lattice strains in the polycrystalline specimens will be presented. These results have been used further to quantify the load partitioning in the elastic regime between the softer bphase and stiffer aphase. In addition, diffraction data were collected along the entire elastic and plastic regime to determine the evolution of lattice strains, texture and phase compositions.

        Speaker: Markus Hoelzel
      • 09:45
        Lamella orientation control of β-Solidifying TNM Alloys via High-Temperature Compression 15m

        The third generation β-solidifying TNM alloys with (α2+γ) lamellar microstructures have been considered excellent candidates for modern turbine blades due to their low density, high specific strength and stiffness, excellent creep resistance, and good corrosion resistance. It has been found that orienting the γ lamellae to the direction of the load can significantly increase the mechanical properties of the alloys, making lamella orientation control (texturization) an interesting topic for property optimization [1].
        In this study, high-temperature compression (with a dilatometer) was first achieved to texturize the alpha phase through optimization of compressive speed and strain. An optimum fiber texture for the alpha phase has been identified by combining EBSD analysis with an in-situ XRD synchrotron.
        Moreover, experiments were performed to observe the effect of the strain rates, taking a high strain rate of 1 s-1 and low strain rate of 10-2 s-1 while keeping the other parameters constant (cooling rates, externally applied load during cooling, total deformation, and temperature). A difference in behavior for the true stress-strain curve has been highlighted corresponding to a different type of mechanisms of dynamic recrystallization.
        Our results show that the microstructure and texture of TiAl alloys can be effectively controlled, and it seems that having a high deformation and a low strain rate should promote the uniform fiber texture.
        Further analyses are needed to understand the mechanisms behind the observed texture evolution. These findings have potential implications for optimizing the processing and performance of TiAl alloys.

        [1] « Polysynthetic twinned TiAl single crystals for high-temperature applications » Chen et al. Nature Materials vol.15 August 2016

        Speaker: Mohamed KEITA
      • 10:00
        Targeted use of residual stress in electrical steel to increase energy efficiency 15m

        Stacked electrical steel sheets compose the magnetic core of electric engines, in which the magnetic flux is guided by cut-outs in the sheets. We developed magnetic flux guidance by targeted residual stress instead of cut-outs to increase the maximum achievable rotational speed of electric engines by increasing the mechanical stability. Due to a combination of limitations, we primarily probed the electrical steel sheets using neutron grating interferometry. To further understand the connection between residual stress and magnetic properties of electrical steel, we would like to discuss additional measurement and simulation techniques, such as strain-mapping, X-ray diffraction or micro-magnetic simulations.

        Speaker: Simon Sebold (MLZ)
      • 10:15
        Defect detection in additively manufactured metal components using neutron grating interferometry 15m

        Additive manufacturing (AM) enables to manufacture of complex shapes ultimately leading to lightweight components. To be certain that the components perform as designed it is necessary to know the types of defects and distributions in the components and their influence on mechanical properties. For this neutron grating interferometry (nGI) can be used to quantify various types of defects and to visualise the defect evolution under loading conditions.

        Speaker: Prabhat Pant (Uppsala University/MLZ)
    • 09:30 10:30
      Parallel 5: New Methods Seminar room roof

      Seminar room roof

      Convener: Dr Sebastian Busch (GEMS at MLZ, Helmholtz-Zentrum Hereon, Germany)
      • 09:30
        Diffraction computed tomography and its applications 15m

        Attenuation-based radiography and tomography (CT) are well-established experimental techniques for non-destructive visualisation of the object interior, where X-/gamma-rays and neutrons are most commonly used types of the incident radiation, but also protons or heavy particles (e.g. ions) can be used as a source. Different radiation sources are used along with phase-contrast, Bragg and/or energy-selective imaging for gathering complementary information enabling the enhancement of contrast and sensitivity beyond the limitations of X-rays.
        Alternative way to increase sensitivity to density variations and chemical composition as well as to improve the discrimination of chemically and morphologically similar, but structurally distinct phases is the accounting for scattering effects in the radiography and tomography. This pawed the way to diffraction CT – an experimental technique combining diffraction with Computed Tomography in the form of either XRD-CT or ND-CT, where similar to traditional CT, the sample is scanned by a pencil-beam, but the diffraction picture is collected instead of the attenuation pattern in the transmitted beam. Prominent progress has been achieved during the last decades in increasing spatial and temporal resolution especially for studies of energy materials, biological samples, catalysts, fuel cells etc.
        In the current contribution we report the applications of diffraction-CT to studies of lithium distribution in commercial cylinder-type Li-ion batteries as well as the implementation and first results of ND-CT (Neutron Diffraction with Computed Tomography) experiments using monochromatic thermal neutrons.

        Speaker: Anatoliy Senyshyn
      • 09:45
        Why elemental analysis is important in neutron scattering centers? 15m

        Elemental analysis with neutrons is based on the excitation of atomic nucleus inducing penetrant gamma rays, thus enabling the non-destructive bulk analysis of samples. With prompt gamma activation analysis (PGAA), all elements can be detected: the higher their neutron capture cross section, the stronger their signal in the gamma spectrum. It is unique in the determination of light elements (like H, B, also D), as well as in the characterization of neutron shielding.
        We have received many inquiries regarding neutron activation analysis (NAA), our new instrument, as it is still one of the most sensitive method for trace elements (Co, Mn, Na, etc.), and is also important in the determination of activating nuclides in structural components.
        PGAA has continuously been developed during the past 15 years with lowering the spectral background, with introducing new 64k digital spectrometers of great potential. We have introduced a low-background counting chamber for determining short-lived beam-activated nuclides. PGAA now also accommodates Neutron Depth Profiling with world-class characteristics.
        We have more ambitious plans for the future: we want to detect all (detectable) particles induced by neutrons to reach a broader circle of elements with higher sensitivities (e.g., P in Si, Pb in bronzes, etc.). The combination of the methods (PGAA+NAA, short-cyclic NAA, PGAA+NDP, PGAA+imaging) open new directions, to which our user community is looking forward.

        Speaker: Dr Zsolt Revay (PGAA)
      • 10:00
        A Bayesian approach to fit Molecular Dynamics (MD) simulations to neutron and X-ray diffraction and spectroscopy data on the example of water 15m

        Most of the established MD water models are optimized to reproduce macroscopic water properties, but are then used to study its nanoscopic structure and dynamics.
        Neutron and X-ray scattering experiments investigate matter on exactly this nanoscopic level and these experiments can be used to optimize the water models on exactly the same time- and length-scale they will be evaluated on.

        In our work, we connect published experimental data of neutron and X-ray experiments on liquid water (diffuse scattering and quasielastic neutron scattering) with MD simulations via a Bayesian fitting algorithm to obtain a set of parameters that can simultaneously fit the real nanoscopic structure and dynamics on an atomic level. To do so, we tie together existing best-of-class tools for MD simulation (LAMMPS) and scattering curve computation (Sassena) using a self-written Bayesian framework that samples the parameter space with a Markov Chain Monte Carlo approach.

        Speaker: Mrs Veronika Reich (GEMS at MLZ, Helmholtz-Zentrum Hereon)
      • 10:15
        LiBH4 as a liquefying catalyst for hydrogen release/uptake from a storage material 15m

        Hydrogen as energy carrier is one of the hot topics aimed at stopping global warming. Hydrogen storage is one of its challenges. The problems of storage in high-pressure vessels and liquefaction (physical methods) are, firstly, high energy requirements and, secondly, hydrogen leaks through vessel walls via diffusion. When stored chemically, $\mathrm{H_2}$ is produced only on demand. This overcomes the escape threat and, provided there are moderate operation conditions, it is also an energy saving method. Lightweight complex hydrides are ionic compounds which consist of an anion complex, where hydrogen is covalently bonded to a central metal or non-metal atom, and one or several metal cations. They have high gravimetric hydrogen density and are capable of reversibly releasing and up-taking hydrogen. Due to their low weight, they are particularly advantageous for mobile applications. Amides ($\mathrm{NH_2^{-}}$), are one class of these light-weight complex hydrides. Obstacles preventing their use are high operation temperatures (energy cost) and the release of $\mathrm{NH_3}$ under heating (due to fuel cell poisoning, which requires regeneration afterwards, and quantitative reduction of the desorbed hydrogen gas). However, when amides are mixed with hydrides (e.g. $\mathrm{Mg(NH_2)_2}$ with $\mathrm{LiH}$), $\mathrm{NH_3}$ is caught by the latter, leading to hydrogen generation. A $\mathrm{6Mg(NH_2)_2−9LiH}$ mixture is in principle a good storage candidate but the kinetics are sluggish and high operation temperatures are required. This is solved when using lithium borohydride $\mathrm{LiBH_4}$ as an additive: it plays the role of a catalyst. Lithium amide $\mathrm{LiNH_2}$, created in the first step of the hydrogen release reaction, forms a mixture with $\mathrm{LiBH_4}$. Two known compounds, $\mathrm{Li_2BH_4NH_2}$ (melting at 90°C) and $\mathrm{Li_4BH_4(NH_2)_3}$ (melting at 190°C), form an ion-conducting liquid at working conditions. It is assumed that this accelerates the reaction. Varying the quantity of $\mathrm{LiBH_4}$ changes the resulting mixture properties by forming different $\mathrm{LiBH_4–LiNH_2}$ mixed phases. I will present the binary phase diagram ( $\mathrm{LiBH_4–LiNH_2}$), obtained from DSC and diffraction measurements, indicating $\mathrm{LiBH_4:LiNH_2}$ ratios with corresponding $\mathrm{6Mg(NH_2)_2:9LiH:xLiBH_4}$ compositions. Such juxtaposition is a prerequisite for understanding the reaction mechanisms in these hydrogen storage materials.

        Speaker: Anastasiia Kuznetsova (HZG)
    • 09:30 10:30
      Parallel 5: Soft Matter 2 Seminar room basement

      Seminar room basement

      Convener: Michaela Zamponi (Forschungszentrum Jülich GmbH, Jülich Centre for Neutron Science at Heinz Maier-Leibnitz Zentrum)
      • 09:30
        Polysaccharide-based nano-/micro-gels for the food sector 15m

        Polysaccharides are the major natural originated components finding extensive investigation and utilization in diverse fields including the nutritional manufacturing sector. Due to their advantageous properties such as safety, stability, biocompatibility, biodegradability and nontoxicity, polysaccharide-based complex systems have a significant potential in the fields of cosmetics, pharmaceutics and food engineering. Microencapsulation of active ingredients such as, flavors, antioxidants, vitamins, lipids into biopolymer nano-/micro-gels offers greater bioavailability, effectiveness, lower toxicity and more lasting stability than conventional formulations. Understanding the physicochemical properties of these micro- and nanogels and their encapsulating and release properties in different conditions is therefore crucial for their optimization and use in the food sector.
        In this communication we present k-carrageenan-based nanogels obtained as a result of coassembly with a-lactalbumin as macro-ionic crosslinking agent. Such systems are of interest as carriers for bioactive ingredients therefore we compared the microstructure and VD3 encapsulation capacity of nanogels as a function of preparation protocol and various environment conditions (pH, T) applying combination of scattering and spectroscopic techniques.

        Speaker: Anastasiia Fanova (JCNS)
      • 09:45
        How is the biological effect of fast neutrons on human tissue mediated? 15m

        In fast neutron therapy with a fission beam, damage to irradiated cells is mainly due to secondary protons and electrons from neutron and gamma interactions, respectively. For the severity of biological effects on cells and the DNA in particular, the occurrence of interaction clusters plays a crucial role. The occurrence of clustered damage differs for neutron and gamma radiation which is reflected in both the application of neutrons in external radiotherapy and the risk evaluation in radiation protection.

        Speaker: Lucas Sommer
      • 10:00
        Effect of Amyloid-β(1-42)-Monomer and protofibrils on dynamics of brain phospholipid liposomes and the Aggregation Kinetics Amyloid-β(1-42) 15m

        The cognitive dysfunctionality stems from Amyloid Aβ (1-42), a neurotoxic peptide which is primarily responsible for Alzheimer's disease and is predominantly found in the extracellular spaces in the form of senile plaques. Aβ42 has a strong propensity to interact with the phospholipid membrane, sphingomyelin, ganglioside GM1, and cholesterol. The plasma membrane is the first biological building block encountered by the Aβ42. Hence, the impact of Aβ42 on the structure and dynamics of the brain phospholipid membrane is important to understand Aβ42 pathogenesis. Furthermore, the aggregation kinetics of Aβ42 in presence of brain phospholipids is of prime interest due neurotoxic behaviour of the Aβ42. We have prepared 100 nm unilamellar vesicles from the brain phospholipids which are mainly composed of phospholipids and sphingomyelin extracted from the porcine brain tissues. Moreover, we have prepared different aggregation states of Aβ42-monomer (M) and proto-fibrils (pf). The unilamellar vesicles were characterized by CryoTEM and Dynamic light scattering and the bilayer thickness is characterized using small angle x-ray scattering. We have investigated the aggregation kinetics of Aβ42 with and without liposomes using Cryo transmission electron microscopy. We have investigated the effect of Aβ42 monomer and protofibrils on the dynamics of unilamellar vesicles using quasielastic neutron scattering. CryoTEM study shows a higher aggregation of amyloid Aβ42 in presence of brain phospholipids and the onset of fibrillation. This study shows Aβ42 brain phospholipids association and the impact of Aβ42 on the dynamics of unilamellar vesicles extracted from brain tissues on the picosecond time scale and Aβ42 fibrillation kinetics.

        Speaker: Purushottam Dubey (JCNS - 4)
    • 10:30 11:00
      Coffee 30m
    • 11:00 11:30
      Plenary 5: TUM CNSI Seminar room ground floor

      Seminar room ground floor

      Convener: Dr Christian Reiter
    • 11:30 12:15
      Plenary 5: Discussion parallel sessions Seminar room ground floor

      Seminar room ground floor

      Convener: Juergen Neuhaus
    • 12:15 13:00
      Plenary 5: Wrap up Seminar room ground floor

      Seminar room ground floor

      Conveners: Prof. Martin Müller (Helmholtz-Zentrum hereon GmbH), Peter Müller-Buschbaum (TU München, Physik-Department, LS Funktionelle Materialien)
    • 13:00 14:30
      Lunch 1h 30m Basement

      Basement

    • 14:30 16:30
      Bus to Garching