NOMAD for Research Data Management in Materials Science
Authors/Creators
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Pielsticker, Lukas
(Contact person)1
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Brockhauser, Sandor1
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Marquez Prieto, Jose Antonio1
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Kühbach, Markus1
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Hildebrandt, Ron
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Mozumder, Rubel
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Shabih, Sherjeel
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Dobener, Florian1
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ALBINO, ANDREA
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Kapoor, Sarthak
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Näsström, Hampus
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Brückner, Sebastian
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Mansour, Ahmed E.1
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Chang, Theodore1
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Ladines, Alvin Noe1
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Himanen, Lauri
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Scheidgen, Markus2, 1
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Haraszti, Tamás3
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Albrecht, Martin
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Hetaba, Walid4
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Rettig, Laurenz2
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Aeschlimann, Martin
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Sturm, Chris
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Grundmann, Marius5
- Spiecker, Erdmann6
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Draxl, Claudia
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Weber, Heiko B.7
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Koch, Christoph1
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1.
Humboldt-Universität zu Berlin
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2.
Fritz Haber Institute of the Max Planck Society
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3.
DWI – Leibniz Institute for Interactive Materials
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4.
Max Planck Institute for Chemical Energy Conversion
- 5. Universität Leipzig
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6.
Friedrich-Alexander-Universität Erlangen-Nürnberg
- 7. Friedrich-Alexander-Universität Erlangen-Nürnberg Naturwissenschaftliche Fakultät
Description
This talk took place on September 25, 2025, as part of the NextGen Materials Conference 2025.
We present an overview of research data management workflows including multidimensional characterization techniques using the NOMAD platform. Our approach focuses on efficiently handling rich metadata as well as large-volume datasets—particularly in HDF5 format—and on the development of specialized NeXus application definitions for emerging characterization methods. We demonstrate how cloud-based analysis tools can be seamlessly integrated into the entire workflow, illustrated by examples from microscopy and spectroscopy techniques (electron microscopy, multidimensional photoemission spectroscopy, Raman spectroscopy, etc.). By leveraging customized JupyterLab environments and desktop-based tools in the cloud, this strategy supports efficient, advanced analyses that remain tightly integrated with the NOMAD data management infrastructure, eliminating the need to relocate large datasets and enhancing data share-ability. Furthermore, we show how instrument inventories and sample metadata can be linked to specific measurements, enabling robust traceability and a comprehensive history throughout the entire materials development lifecycle.
This work is funded by the NFDI consortium FAIRmat - Deutsche Forschungsgemeinschaft (DFG) - Project 460197019
Files
2025-06-25_NextGenMaterials_Pielsticker.pdf
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(3.9 MB)
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Additional details
Funding
Dates
- Available
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2025-09-25