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A true atomic movie shot by pulse twins with a giant X-ray laser

How do atoms move when a liquid flows or a hot glass changes shape? Their motion happens so quickly in a seemingly random manner. Yet researchers have…

iMAT is now AU Materials

The official description has changed from research center to cluster. What we do, and why we do it, remains the same. If you are looking for…

From Vacuum Chambers to Devices: Bridging Surface Science and Industrial Catalysis

Microscopic view of a porous nickel foam electrode overlaid with a schematic of the oxygen evolution reaction (OER), highlighting how hydrogen and oxygen are split during electrochemical water splitting.

Understanding how catalysts work at the atomic level is key to designing better technologies for green hydrogen production. In his PhD at the…

Catalyst Combinations That Work: What Real-Time Studies Reveal About Performance and Stability

Thesis cover featuring a greyscale electron microscopy image of mixed-metal nanoparticles with the title “Electrocatalytic Performance and in situ Guided Synthesis of Solid Solutions” and the author name Andreas Dueholm Bertelsen.

In his PhD at the Department of Chemistry, Andreas Dueholm Bertelsen explored how combining different metals into complex alloys can improve catalysts…

Small Ions, Big Impact on Gold Nanoparticle Formation

New research from researchers at Aarhus University shows how simple changes in counterions during synthesis affect the stability and quality of gold…

The Quest for Room-Temperature Emission in GeSn

Graphic of a germanium-tin (GeSn) semiconductor crystal structure with a laser beam passing through, representing optical excitation used to study carrier dynamics in Martin Aagaard’s PhD research.

GeSn alloys are a promising material for integrating infrared light sources directly on silicon chips. In his PhD project at the Department of Physics…

Tuning Chemistry at the Interface: How Molecular Additives Are Changing CO₂ Reduction

Close-up scientific illustration showing how carbon dioxide molecules interact with a copper catalyst surface during electrochemical CO₂ reduction. A zoomed-in view highlights how molecular additives bind near the catalyst and influence the formation of multi-carbon products.

In her PhD at the Interdisciplinary Nanoscience Center and Department of Chemistry, Kirstine Nygaard Kolding explored how small organic molecules can…

Lighting Up Cancer Detection: Exploring New Materials for Medical Scanners

Medical scans like PET are vital tools for detecting and diagnosing cancer. At the heart of these scanners are materials called scintillators, which…

Disorder at the Surface: Ultrafast Changes in La0.5Sr1.5MnO4

A new study on the quantum material La0.5Sr1.5MnO4 reveals that its response to light is more complex than expected. Using ultrafast X-ray pulses,…

Layer by Layer: Building Catalysts That Tackle CO₂ and Water Pollution

In her PhD project at Aarhus University, Ronghui Lu set out to design advanced materials that can address two major environmental challenges:…

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Revised 17.04.2026