➀ Marco Stucki won the Berlin University Alliance's ideas competition with a novel method for creating diamond nanostructures for quantum technologies, enabling future quantum computing and secure communication networks;

➁ The competition showcased Berlin's diverse research fields, attracting over 80 submissions spanning global health, climate, and quantum technologies;

➂ Stucki's "Sawfish Cavity" uses diamond-based optical resonators to trap and amplify light, with artistic visualizations displayed publicly in Berlin as part of the campaign.

➀ Prof. Karl Leo, a leading scientist in solid-state physics and optoelectronics at TU Dresden, received Saxony's highest state honor for his transformative contributions to the region's research landscape;

➁ His pioneering work on organic semiconductors led to breakthrough OLED technologies now used globally in displays, alongside advancements in solar cells and biodegradable electronics;

➂ A serial entrepreneur, Leo founded 11 startups like Novaled and Heliatek, strengthening Silicon Saxony's tech ecosystem and earning prior accolades including the Leibniz Prize and European Inventor Award.

➀ A German-Dutch research team led by Helmholtz-Zentrum Dresden-Rossendorf (HZDR) discovered that hydrogen bubbles in electrolyzers contain electrolyte microdroplets, revealing internal flow dynamics for the first time;

➁ The study identified that gas bubbles merge and create microjets of electrolyte, forming droplet clouds that reduce efficiency by altering electrode contact and delaying bubble detachment;

➂ Findings, published in Nature Communications, provide insights into improving electrolyzer efficiency, with ongoing research funded by BMBF and NWO to address technical challenges.

➀ Researchers discovered luminous quasiparticles (excitons) on the surface of the antiferromagnetic semiconductor CrSBr, challenging the belief that they could only exist within the material;

➁ Using ultrafast microscopy and spectroscopy, the team visualized surface excitons in ultra-thin crystal layers, noting distinct optical properties compared to internal excitons;

➂ The international collaboration highlights potential applications in energy storage, quantum information, and photonics-magnetism hybrid technologies.

➀ Researchers discovered surface-bound excitons (quasiparticles) on the antiferromagnetic semiconductor chromium-sulfur-bromide (CrSBr), previously thought to form only within materials;

➁ The magnetic order of CrSBr enables precise control of light absorption and emission via magnetic fields, leveraging its ultrathin van der Waals crystal structure;

➂ International collaboration confirmed the reproducibility of findings, highlighting potential for technologies integrating photonics and magnetism.

➀ Johannes Gutenberg University Mainz's Professor Jairo Sinova will coordinate a new Priority Program focusing on unconventional magnetism in condensed matter physics.

➁ The program aims to develop IT components that push the technical limits of speed, storage density, and efficiency.

➂ The German Research Foundation (DFG) has approved the program with around EUR 8 million in funding over three years.

➀ A new DFG special research program aims to utilize unconventional magnetism for information technology.

➁ The program, coordinated by Prof. Dr. Jairo Sinova of Johannes Gutenberg-Universität Mainz, focuses on fundamental and applied research.

➂ The goal is to develop components or devices with unprecedented speed, storage density, and efficiency based on unconventional magnetic systems.

Researchers at the European XFEL have developed a new measuring device for hard X-ray light, known as a Laue spectrometer. It can detect photon energies over 15 kiloelectronvolts with high precision and improved efficiency. This is important for the study of technologically significant materials, such as those capable of transporting electricity without loss or enhancing the efficiency of chemical processes.

Traditional X-ray spectrometers operate in the Bragg geometry, where X-rays are bent by parallel atom planes, similar to mirrors reflecting visible light. However, at high energies, much of the hard X-ray light passes through the crystal unused, reducing the performance of conventional spectrometers. The new Laue spectrometer developed at the FXE experimental station at the European XFEL addresses this issue by working in the Laue geometry, where X-rays pass through the crystal and are bent by atomic layers perpendicular to the surface. This makes the new Laue analyzer more efficient at higher X-ray energies.

The newly developed device, called the High Energy Laue X-ray Emission Spectrometer (HELIOS), is now available to all users at the European XFEL. It offers an extremely high precision of about 1.2 x 10^-4 at a photon energy of about 18.6 keV, reaching 4 to 22 times higher signal strength compared to conventional spectrometers. This allows the detection of particularly interesting electronic transitions in so-called 4d-transition metals, which are otherwise very difficult to measure.

➀ Researchers from Tokyo University of Science and other institutions have discovered antiferromagnetism in quasicrystals for the first time.

➁ The discovery was made in a novel Tsai-type gold-indium-europium (Au-In-Eu) iQC with unusual symmetries.

➂ The research suggests that quasicrystals with a positive Curie-Weiss temperature are more likely to establish antiferromagnetic order.

The ultrafast dynamics and interactions of electrons in solids have been a challenge to observe directly. Researchers from the University of Oldenburg and Politecnico di Milano have developed a new spectroscopic method that uses ultra-short laser pulses to analyze the movement of electrons in materials. This method, known as two-dimensional electronic spectroscopy (2DES), allows for the study of quantum-physical processes with high temporal resolution. The team has found a way to simplify the experimental implementation of this procedure, making it more accessible for wider use.

The research involves using a sequence of three ultrashort laser pulses to excite electrons in a material, changing its optical properties, and then using a third pulse to provide information about the excited system. By varying the time intervals between these pulses, different stages of the process can be observed. The team's new approach, which involves adding an optical component to an interferometer, has significantly improved the precision of the laser pulses.

This breakthrough could lead to new insights into various quantum-physical processes, such as chemical reactions and energy transfer in solar cells.

➀ The Technical Collections Dresden are highlighting quantum physicists on International Women's Day 2025.

➁ The traveling exhibition 'RETHINKING PHYSICS. 100 Years of Quantum Mechanics: Time for a Female Perspective!' will open with portraits of established and emerging researchers.

➂ The exhibition aims to make women in the natural sciences more visible, promote role models, and encourage questioning the structures in the scientific culture.

➀ Students from the University of Stuttgart are launching a ferrofluid experiment aboard the REXUS sounding rocket from the European spaceport in Sweden between March 10 and 15, 2025.

➁ The mission aims to explore the performance of ferrofluid-based technologies in weightless conditions and under extreme forces and temperatures.

➂ The use of magnetic fluid is intended to improve technologies for space travel, focusing on durability and sustainability.

Researchers have developed a novel method to track light fields directly within optical resonators. This enables precise measurements at the exact locations where future field-resolved studies of light-matter interactions will take place.

Scientists from the Department of Physical Chemistry at the Fritz-Haber Institute of the Max Planck Society and the Helmholtz-Zentrum Dresden-Rossendorf have developed a new experimental platform to measure the electric fields of light trapped between two mirrors with precision below a light cycle. These electro-optical Fabry-Pérot resonators allow for precise control and observation of light-matter interactions, particularly in the terahertz (THz) spectral region.

Through the development of a tunable hybrid resonator design and the measurement and modeling of its complex mode spectrum, physicists can now actively switch between nodes and maxima of light waves at relevant resonator locations. This study thus opens new paths for the exploration of quantum electrodynamics and the ultrafast control of material properties.

➀ ISTA physicists have achieved a breakthrough in quantum computing by achieving a fully optical readout of superconducting qubits.

➁ This breakthrough could help scale up quantum computers by reducing the amount of cryogenic hardware needed.

➂ The technology could lead to the development of quantum computing networks connected via optical fibers.

Physicists from the University of Stuttgart have discovered a hidden symmetry in exotic quasikristalline crystals. This symmetry is hidden in a higher spatial dimension, revealing a new type of order in quasikristalls. The research, published in Science, could have implications for quantum computing and stable information storage.

➀ The Kavli Foundation, the Klaus Tschira Foundation, and Kevin Wells have launched a research project to develop next-generation superconducting materials;

➁ The project will be led by Päivi Törmä of Aalto University, focusing on quantum geometry in 3D materials;

➂ Artificial intelligence will be used to predict material properties for revolutionary levels of superconductivity.

➀ Researchers at the Fritz-Haber Institute have made progress in electrocatalysis, revealing how catalysts can remain in unexpected forms during nitrate reduction processes.

➁ The study, published in Nature Materials, uses advanced microscopy and spectroscopy techniques to observe changes in catalysts during reactions, challenging previous assumptions about catalyst behavior.

➂ The findings could pave the way for more efficient catalyst designs, particularly in ammonia production from nitrates, offering a potential alternative to traditional Haber-Bosch process with reduced carbon emissions.

➀ Researchers at TU Wien have discovered a new physical phenomenon that exists between metals and insulators, which they describe as a 'quantum umbilical cord.';

➁ This phenomenon occurs when the interaction strength between electrons is sufficiently large, leading to additional energy states between metallic and insulating materials;

➂ The discovery opens up new perspectives in material science and technology, suggesting that there are more states between conductors and insulators than previously thought.