Highlighted in
Science & Tech

Physics & Astronomy
5 mins read

Unravelling Coronal Mass Ejections from Our Solar System’s Origin

Young stars ejecting plasma could give us clues into the Sun’s past Kyoto, Japan — Down here on Earth we don’t usually notice, but the Sun is frequently ejecting huge masses of plasma into space. These are called coronal mass ejections (CMEs). They often occur together with sudden brightenings called flares, and sometimes extend far enough to disturb Earth’s magnetosphere, generating space weather phenomena including auroras or geomagnetic storms, and even damaging power grids on occasion. Scientists believe that when…

Read more

All News

Physics & Astronomy

New Lattice Calculations Refine Proton Radius Measurements

Theoretical physicists at PRISMA+ Cluster of Excellence present new comprehensive lattice calculations. A group of theoretical physicists at Johannes Gutenberg University Mainz (JGU) has once again succeeded in significantly improving their calculations of the electric charge radius of the proton published in 2021. For the first time they obtained a sufficiently precise result completely without the use of experimental data. With respect to the size of the proton, these new calculations also favor the smaller value. Concurrently, the physicists for…

Physics & Astronomy

Efficient Perovskite Cells with Anti-Reflective Layer Boost Solar Innovation

– another step towards commercialization on a wider scale. Perovskite-based solar cells, widely considered as successors to the currently dominant silicon cells, due to their simple and cost-effective production process combined with their excellent performance, are now the subject of in-depth research. A team of scientists from the Fraunhofer Institute for Solar Energy ISE and the Faculty of Physics at the University of Warsaw presented perovskite photovoltaic cells with significantly improved optoelectronic properties in the journal Advanced Materials and Interfaces….

Physics & Astronomy

Astronomers Uncover Key Signs of Planet Formation

Astronomers have gotten very good at spotting the signs of planet formation around stars. But for a complete understanding of planet formation, we also need to study examples where planet formation has not yet started. Looking for something and not finding it can be even more difficult than finding it sometimes, but new detailed observations of the young star DG Taurus show that it has a smooth protoplanetary disk without signs of planet formation. This successful non-detection of planet formation…

Physics & Astronomy

New Device Enhances Network Interface for Quantum Computers

A team of scientists at the QOT Centre for Quantum Optical Technologies, including a student from the Faculty of Physics (University of Warsaw), made a device capable of the conversion of quantum information between microwave and optical photons. The results of research, published in “Nature Photonics” magazine, highlight a new microwave detection method with possible applications in quantum technologies, as a part of quantum network infrastructure, and in microwave radio-astronomy.  Conversion of quantum information Whenever you listen to a song…

Physics & Astronomy

Highest Energy Gamma Rays Detected From Vela Pulsar

H.E.S.S. observatory records 20 tera-electronvolts photons from the Vela pulsar. Scientists using the H.E.S.S. observatory in Namibia have detected the highest energy gamma rays ever from a dead star called a pulsar. The energy of these gamma rays clocked in at 20 tera-electronvolts, or about ten trillion times the energy of visible light. This observation is hard to reconcile with the theory of the production of such pulsed gamma rays, as the international team reports in the journal Nature Astronomy….

Physics & Astronomy

NIST’s New Quantum Ruler Explores Exotic Matter Using Graphene

NIST researchers find a new quantum ruler to explore exotic matter. A single-atom-thick sheet of carbon known as graphene has remarkable properties on its own, but things can get even more interesting when you stack up multiple sheets. When two or more overlying sheets of graphene are sightly misaligned — twisted at certain angles relative to each other — they take on a plethora of exotic identities.Depending on the twist angle, these materials, known as moiré quantum matter, can suddenly…

Information Technology

New Qubit Platform Built Atom by Atom Advances Quantum Science

Researchers at the IBS Center for Quantum Nanoscience (QNS) at Ewha Womans University have accomplished a groundbreaking step forward in quantum information science. In partnership with teams from Japan, Spain, and the US, they created a novel electron-spin qubit platform, assembled atom-by-atom on a surface. This breakthrough was published in the journal Science on 2023/10/06. Unlike previous atomic quantum devices on surfaces where only a single qubit could be controlled, the researchers at QNS successfully demonstrated the ability to control…

Physics & Astronomy

Testing Quantum Electrodynamics: New Insights on Electron g Factor

Measurement of the g factor of the electron in hydrogen-like tin confirms the standard model of particle physics under extremely high electric field strengths. Quantum electrodynamics is the best-tested theory in physics. It describes all electrical and magnetic interactions of light and matter. Scientists at the Max-Planck-Institut für Kernphysik in Heidelberg (MPIK) have now used precision measurements on their Alphatrap experiment to investigate the magnetic properties of electrons bound to highly ionized tin atoms. Such tests provide insights into the…

Physics & Astronomy

Molecular knots – left and right: How molecules form knots

Plastics or DNA: Many molecules are so long that they can form knots, much like tying shoes. Whereas it is still disputed whether right- and left-handed people prefer to tie their knots in different directions, the knotting habits of molecules are now made much clearer. A team of researchers from the Max Planck Institute for Polymer Research and the Johannes Gutenberg University, Mainz has demonstrated that the direction of the twist of helical molecules – right or left – determines…

Information Technology

Europe’s exascale supercomputer in its starting blocks

Following last year’s selection of Forschungszentrum Jülich as the hosting entity, it has now also been decided who will supply JUPITER, Europe’s first exascale supercomputer: a bidding consortium by the German supercomputing and quantum computing company ParTec AG and Eviden, the advanced computing division of the French IT service provider Atos. The “Joint Undertaking Pioneer for Innovative and Transformative Exascale Research,” or JUPITER for short, will be the first system in Europe capable of more than 1 exaflop/s. This number…

Physics & Astronomy

Laser system to defend space assets from debris in Earth’s orbit

If West Virginia University research pays off, debris that litters the planet’s orbit and poses a threat to spacecraft and satellites could get nudged off potential collision courses by a coordinated network of space lasers. Hang Woon Lee, director of the Space Systems Operations Research Laboratory at WVU, said a junkyard of human-made debris, including defunct satellites, is accumulating around Earth. The more debris in orbit, the higher the risk that some of that debris will collide with manned and unmanned space…

Physics & Astronomy

Navigating moiré physics and photonics with band offset tuning

New approach to controlling moiré flatbands adjusts band offset of two photonic lattices. When two lattices with distinct angles or periodicities come together, they conjure a moiré superlattice — a realm where astonishing phenomena like superconductivity and optical solitons spring to life. At the heart of this realm lies the moiré flatband, a key player in shaping advanced light–matter interactions, such as laser emission and second harmonic generation. In moiré physics and its relevant applications, wielding control over flatbands is…

Information Technology

Unlocking Qubits: Atomic-Scale Simulations Illuminate Spin Defects

By using sophisticated computer simulations at the atomic scale, a new study predicts the formation process of spin defects useful for quantum technologies. Researchers led by Giulia Galli at University of Chicago’s Pritzker School of Molecular Engineering report a computational study that predicts the conditions to create specific spin defects in silicon carbide. Their findings, published online in Nature Communications, represent an important step towards identifying fabrication parameters for spin defects useful for quantum technologies. Electronic spin defects in semiconductors…

Physics & Astronomy

Superconducting Niobium Waveguide Boosts B5G/6G Communications

A team of researchers has made a breakthrough discovery in the world of Beyond 5G/6G (B5G/6G) signal transmission. Taku Nakajima and Kazuji Suzuki of Nagoya University in Japan, along with their collaborators, created a waveguide made of niobium that speeds up the transition of B5G/6G signals. The frequency of data waves has continued to increase as B5G/6G technologies have been introduced. Although the currently used metal transmission lines can handle B5G/6G, research has focused on superconducting metals, such as niobium,…

Information Technology

AI Creates New Robot Designs in Seconds: A Breakthrough Insight

Instant evolution: First AI capable of intelligently designing new robots that work in the real world. Inventor of xenobots unveils new advance toward artificial life New AI algorithm compresses billions of years of evolution into seconds The evolved robot has three legs and rear fins, something a human engineer would never devise Researcher: ‘Now anyone can watch evolution in action as AI generates better and better robot bodies in real time.’ A team led by Northwestern University researchers has developed…

Physics & Astronomy

UV Diodes in Mars Mission: Advancing Space Sensor Tech

Sensor Technology with Silicon Carbide for Use in Space. When it comes to particularly low-loss semiconductor components and highly efficient power electronics, there is no way around silicon carbide (SiC) today. The wide-bandgap semiconductor material SiC is superior to conventional silicon in many respects and is conquering more and more new areas of application, for example in optoelectronics, sensor technology or solid-state quantum electronics. Even in space, SiC demonstrates its outstanding physical properties: A SiC UV photodiode from the Berlin-based…

Feedback