Scientific Events

Recent applications of high-energy-resolution STEM-EELS: from phonons and magnons to extra-terrestrial organic matter

  • Date: Jul 17, 2026
  • Time: 11:00 AM - 12:00 PM (Local Time Germany)
  • Speaker: Prof. Quentin Ramasse
  • Director, SuperSTEM Laboratory and Chair of Advanced Electron Microscopy, University of Leeds
  • Location: Max Planck Institute for Sustainable Materials
  • Room: Large Conference Room No. 203
  • Host: on invitation of Prof. Gerhard Dehm
A little over a decade after the first report of vibrational spectroscopy in the STEM, this informal seminar will illustrate the extremely wide impact high-energy-resolution STEM-EELS has had across numerous scientific fields. Beyond headline demonstrations of atomic-resolution phonon or magnon spectroscopy, which provide a unique tool to probe quantum matter and phenomena at device-relevant length-scales, these new instruments have also found cross-disciplinary applications in areas of research as varied as cosmochemistry (with nanoscale vibrational analysis of the molecular constitution of extraterrestrial organic matter in returned samples from JAXA’ Hayabusa2 or NASA’s OsirisREx missions), fundamental inorganic chemistry (with ‘extreme’ encapsulated nano-systems offering atomic-scale ‘test-tubes’ to study gas or molecular interactions a handful of one molecules at a time) or metallurgy with new insights provided into decades old unresolved debates, e.g. concerning heterogeneous nucleation in metallic alloys). With further instrumentation developments on the horizon such as new sample stages reaching temperatures as low as a few K, there is now truly a synchrotron in our microscopes! [more]

Hydrogen Plasma Refining Coupled with Solid-State Reduction for Sustainable Ironmaking

Hydrogen Plasma Refining Coupled with Solid-State Reduction for Sustainable Ironmaking
  • Date: Jul 8, 2026
  • Time: 03:00 PM - 04:00 PM (Local Time Germany)
  • Speaker: Dr Raj Kumar Dishwar
  • Assistant Professor (Extractive Metallurgy) Department of Fuel Minerals and Metallurgical Engineering Indian Institute of Technology, Dhanbad
  • Location: Max Planck Institute for Sustaianble Materials
  • Room: Big seminar room
  • Host: on invitation of Prof. Dierk Raabe
  • Topic: Discussion and debate formats, lectures
The growing demand for sustainable ironmaking and steel refining technologies has intensified the need for efficient utilization of industrial fines and low-grade resources. In the present study, waste iron ore fines and lime fines were utilized to produce highly fluxed iron ore pellets and their potential application in molten pig iron refining was systematically investigated. Pellets with varying basicity were prepared and hardened at elevated temperatures to evaluate their phase evolution, mechanical properties, reducibility, and refining performance.Mineralogical characterization revealed hematite as the dominant phase in the iron ore, while increasing pellet basicity promoted the formation of calcium ferrite and dicalcium ferrite phases. The development of calcium ferrite significantly enhanced pellet strength, with pellets fired at 1200°C exhibiting strengths exceeding 500 kg/pellet. Reduction studies carried out under both carbonaceous and hydrogen atmospheres demonstrated that pellet basicity strongly influenced reduction kinetics and metallization behavior. Hydrogen reduction resulted in superior reducibility, achieving up to 90% reduction, and produced characteristic iron whisker morphologies that facilitated rapid oxygen removal.The performance of partially and highly reduced fluxed pellets was further evaluated for impurity removal from molten pig iron during electric arc, induction, and plasma-assisted melting operations. Thermodynamic and kinetic analyses revealed that the removal efficiencies of silicon, manganese, phosphorus, sulfur, and carbon were strongly dependent on the reduction degree of the fluxed pellets. Highly reduced pellets exhibited enhanced desulfurization capability, while partially reduced pellets were found to be more effective for phosphorus removal. Plasma-assisted refining under hydrogen atmosphere demonstrated remarkable impurity removal efficiencies, particularly for carbon, silicon, and sulfur.The study establishes a sustainable pathway for the valorization of iron ore and lime fines through the production of highly fluxed direct reduction pellets. The findings demonstrate that appropriately engineered fluxed pellets can serve not only as iron-bearing feedstock but also as multifunctional refining agents for efficient impurity removal during secondary steelmaking operations, contributing to resource conservation and low-carbon ironmaking. [more]

High-performance magnets for efficient energy conversion

  • Date: Jun 24, 2026
  • Time: 02:00 PM - 03:00 PM (Local Time Germany)
  • Speaker: Prof. Dagmar Goll
  • Aalen University: Senior member of the management team at the Institute for Materials Research (IMFAA), Chair of Physics of Magnetic Materials
  • Location: Max Planck Institute for Sustaianble Materials
  • Room: Large Conference Room No. 203
  • Host: on invitation of Prof. Dierk Raabe
Efficient energy converters require high-performance magnetic materials such as rare earth permanent magnets. Due to the criticality of rare earth metals, the major challenges are the reduction or avoidance of those elements in permanent magnets and to optimize the microstructure to approach theoretical predictions of micromagnetism. For better sustainability, it is furthermore expected for the materials to secure long-lasting use with subsequent recycling options. Possible solutions include: (1) In-depth quality assessment of magnets: A good process quality is the prerequisite for a long magnet lifetime. Defects cause premature demagnetization and thus aging of the magnets. Different microscopy techniques in combination with quantitative image analysis as well as component testing are developed as tools for quality assurance. (2) Tailoring and optimization of materials to the requirements of the electrical machine: Starting from well-known microstructure-property relations the magnetic properties can be tailored from a sustainability and economic point of view. Ce-substituted magnets and directly recycled magnets are particularly promising. (3) Identification of new materials and new technologies: Bulk high-throughput methods allow to explore completely new hard magnetic phases. The extent to which laser powder bed fusion additive manufacturing can lead to good magnetic properties and new perspectives needs to be examined. The presentation gives insight into the different solutions. [more]

Ferroelectric Oxides for Sustainable Nanotechnology

Colloquia Series on Sustainable Metallurgy
  • Date: Jun 23, 2026
  • Time: 04:00 PM - 05:00 PM (Local Time Germany)
  • Speaker: Dennis Meier, Functional Ferroic Systems, University of Duisburg-Essen
  • Location: University Duisburg-Essen, Lotharstraße 1, 47057 Duisburg
  • Room: MG 272
  • Host: on invitation of Prof. Christof Schulz
  • Topic: Lectures
[more]

Extreme mechanics and additive manufacturing of materials across scales

  • Date: Jun 1, 2026
  • Time: 01:00 PM - 02:00 PM (Local Time Germany)
  • Speaker: Dr. Yu Zou
  • Associate Professor in the Department of Materials Science & Engineering at the University of Toronto, Canada
  • Location: Max Planck Institute for Sustainable Materials
  • Room: Large Conference Room No. 203
  • Host: on invitation of Prof. Gerhard Dehm
Innovations in material development and manufacturing processes for extreme conditions are necessary and urgent for many emerging applications. Towards this vision, this presentation will focus on the exploration of mechanical behavior and manufacturing processes of materials, with an emphasis on metals and semiconductors, across many length- and time-scales, including the following topics: (i) Controlling dislocation motion and plasticity in semiconductors using non-mechanical stimuli (high electric field or illumination); (ii) Design of high-strength and thermal stability of nanostructured high-entropy alloys using a high-throughput strategy and electrodeposition; (iii) laser-based additive manufacturing and cold spray additive manufacturing of titanium alloys, high-entropy alloys and multi-materials; (iv) machine learning for microstructure design and process optimization. [more]

11th APT User Meeting 2024

  • Start: May 19, 2026
  • End: May 21, 2026
  • Location: Max Planck Institute for Sustaianble Materials
  • Host: Prof. Baptiste Gault, Dr. Tim Schwarz & Dr. Aparna Saksena
  • Contact: t.schwarz@mpie.de
We’re pleased to announce the 11th edition of our world-famous NRW-APT user meeting, hosted at the Max-Planck-Institute für Nachhaltige Materialien from 19th to 21st May 2026. As a follow-up to the success of the 10th NRW user-meeting, we aim to bring again together APT users from not only NRW, but also from all across Europe! We expect an emphasis on:cryo-APT and cryo-developments for specimens preparation Bio-minerals and bio-materialsAPT for hydrogen analysis and related applicationsAPT for energy materialsNanostructure in metals and semiconductorsmachine-learning for APT data processingFundamentals of field evaporation and Field ion microscopyAdvancement in correlative techniques [more]

The Promise of Halide-Perovskite Solar Photovoltaics

  • Date: May 12, 2026
  • Time: 02:00 PM - 03:00 PM (Local Time Germany)
  • Speaker: Prof. Nitin P. Padture
  • Otis E. Randall University Professor, School of Engineering; Director, Initiative for Sustainable Energy; Brown University, USA
  • Location: Max Planck Institute for Sustainable Materials
  • Room: Large Conference Room No. 203
  • Host: on invitation of Prof. Dierk Raabe / Prof. Gerhard Dehm
Renewable electricity from solar photovoltaics (PV), combined with low-cost large-scale storage, is likely to play a dominating role in decarbonizing the expanding global power sector in the long run. For example, the global deployment of PV is targeted at ~75 TW installed capacity by 2050, from the current (2025) ~2.5 TW. While currently used PV technologies are efficient, reliable, and relatively cheap, there is, and always will be, insatiable demand for new PV technologies that are more efficient and cost-effective, and importantly, have a smaller ‘carbon-footprint.’ In this context, the promising new PV technology based on a fascinating class of halide-perovskite materials has the potential to meet all those requirements. Perovskite thin-film PV can be mechanically rigid or flexible, where the latter lightweight PV are more versatile with the potential to power internet-of-things, vehicles, satellites, portable supplies, etc., in addition to rooftop and utility-scale applications. While the record power-conversion efficiency of perovskite PV now rivals that of conventional silicon PV, durability and mechanical reliability are becoming ‘bottleneck’ challenges in perovskite PV. To address some of these technical hurdles in the path towards their commercialization, we have researched several rationally-designed microstructural and interfacial tailoring approaches. These include grain-coarsening, grain-boundary functionalization, and engineering of interfaces and substrates. Most importantly, these approaches are designed to not only enhance the PVs’ mechanical performance but also increase efficiency and improve durability simultaneously. The scientific rationales for these approaches will be discussed, together with the presentation of current results. [more]
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