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Category: computing

Fragile no more, nickelates get an upgrade that changes how superconductivity endures

Discovered in 2019, the material known as nickelates has intrigued researchers for its potential to become a superconductor at elevated temperatures—a property that could significantly advance such fields as quantum science and energy transmission. However, it’s a very unstable material and difficult to work with. But the lab of Professor Charles Ahn has developed a method that could enhance superconductivity in these materials. The results are published in Nature Communications.

With their ability to conduct electricity with no resistance, superconductors are a key component to quantum computing, medical imaging, and a number of other fields. A group of copper-oxide compounds known as cuprates have long been central to the study of high-temperature superconductivity (“high temperature” is a relative term—they still need to be kept in very cold environments). Nickelates are especially exciting because they share some of cuprates’ key electronic features while offering a new platform for materials design and tuning.

Enter nickelates, a material with many similarities to cuprates, but with the potential to eventually become even more useful to scientists. Dung Vu, a postdoctoral associate who led the study, noted that synthesizing nickelate thin films is “notoriously difficult.” The Ahn lab is one of the few in the world with the ability to do so.

Extreme stability in ultrafast nanomagnetism aids the development of faster data storage

For the first time, researchers have mapped how the boundaries of magnetic nanostructures behave on extremely short timescales. The work of physicist Johan Mentink of Radboud University shows that these boundaries are much more stable than previously thought. This insight will aid the development of future ultra-fast and compact data storage.

Every magnet consists of tiny magnets, known as spins. When a material is magnetic, these spins all point in the same direction. Using ultra-short laser pulses, the spins in magnetic materials can change direction in a very short time. This so-called ultrafast nanomagnetism is important for, for example, hard drives, on which information is stored using magnetic bits. To make this storage faster and smaller, it is essential to understand exactly what happens at the nanoscale.

Using a new imaging technique capable of tracking processes down to the nanometer and femtosecond scale, Mentink and colleagues have researched the behavior of domain boundaries—thin walls of about 1 nanometer that separate magnetic domains. Multiple spins pointing in the same direction form a domain.

CERN’s Medipix3 technology on track to help more patients

Originally derived from a technology developed to explore the fundamental nature of the Universe, Medipix3 technology now powers a medical scanner that is on track to benefit an increased number of patients. MARS Bioimaging Ltd has received 510(k) clearance from the US Food and Drug Administration (FDA) for its portable photon-counting CT scanner for upper-limb imaging, allowing the system to enter the US health sector and enable broader clinical adoption.

Medipix technology is based on hybrid pixel detectors, which were originally designed at CERN for particle detection in high-energy physics experiments. This technology was adapted to create the Medipix family of pixel detector readout chips, enabling a new approach to medical imaging.

Unlike conventional CT (computed tomography) systems – which combine X-ray measurements taken from different angles to produce a 3D image – photon-counting technology measures individual X-ray photons and their energy. This produces detailed, three-dimensional images that help clinicians to distinguish between different types of tissue and materials, better informing their decision making. As Dr John Carrino, a prominent musculoskeletal radiologist involved in clinical trials with MARS Bioimaging, notes: “Photon-counting CT is going to be the future of CT for medical imaging.”

Chip Can Project Video the Size of a Grain of Sand

Engineers have created a 1-square-millimeter chip that can project a photograph onto an area smaller than the size of two human egg cells. This precise laser control could have applications in augmented reality, biomedical imaging, and quantum computing.

MEMS array to steer lasers for quantum computer finds other uses.

Experimental Evidence That Universe Could Just Vanish One Day

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Hello and welcome! My name is Anton and in this video, we will talk about a false vacuum experiment that shows us one day the universe could just vanish
Links:
https://arxiv.org/pdf/2512.04637
Previous video: • Experimental Evidence of a Phenomenon That…
#falsevacuum #physics #science.

0:00 Can universe just kind of end?
1:10 New study and an experiment
2:08 What is false vacuum?
4:35 True vacuum transition
5:30 What would happen to the universe?
6:20 Experimental system and a molecular analog
8:10 Previous experiments and achievements
9:30 Explanation the inflation
10:20 Should we be worried?
11:35 Implications for physics.

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New ‘Pack2TheRoot’ flaw gives hackers root Linux access

A new vulnerability dubbed Pack2TheRoot could be exploited in the PackageKit daemon to allow local Linux users to install or remove system packages and gain root permissions.

The flaw is identified as CVE-2026–41651 and received a high-severity rating of 8.8 out of 10. It has persisted for almost 12 years in the PackageKit daemon, a background service that manages software installation, updates, and removal across Linux systems.

Earlier this week, some information about the vulnerability has been published, along with PackageKit version 1.3.5 that addresses the issue. However, technical details and a demo exploit have been not been disclosed to allow the patches to propagate.

One-way phonon synchronization could survive noise and defects, theoretical physicists suggest

A novel approach for realizing the one-way quantum synchronization of phonons has been proposed by three theoretical physicists at RIKEN. Importantly, this method is remarkably resilient against practical challenges such as imperfections and environmental noise. Their paper, “Nonreciprocal quantum synchronization,” is published in Nature Communications.

Many devices use components that act as one-way streets, allowing particles to travel in one direction, but almost not at all in the opposite one. These so-called nonreciprocal components are widely used in microwave and light-based systems for things such as controlling signal flow and preventing reflections.

“Nonreciprocal components enable signals to travel along desired paths, whereas they are strongly attenuated in the opposite direction,” notes Franco Nori of the RIKEN Center for Quantum Computing (RQC). “This ability finds applications ranging from signal processing to invisible cloaking.”

Quantum ‘dark modes’ no longer block phonon control, opening new paths for scalable devices

Three RIKEN researchers have demonstrated a way to stop problematic “dark modes” from squelching intriguing effects in quantum systems. This advance could help with the development of more versatile quantum devices that can be used to control the storage and transmission of quantum information. The study is published in the journal Nature Communications.

Manipulations that alter the topology of certain quantum systems known as non-Hermitian systems are attracting increasing attention, since they offer novel possibilities for manipulating particles of sound (phonons) and light (photons) as well as other excitations.

Topological operations allow for various weird and fascinating phenomena, such as the buildup of chiral phases and the movement of phonons in one direction,” notes Franco Nori of the RIKEN Center for Quantum Computing (RQC).

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