The exploration of topological phases of matter has opened an intriguing chapter in condensed matter physics, revealing states that exhibit remarkable resilience to external disturbances. However, this robustness comes with a price: it introduces a concept known as “topological censorship,” which obscures significant microscopic details pertaining to these unique quantum states. A recent investigation conducted
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The field of nuclear physics has long been fascinated by the intricate interactions that govern the behavior of subatomic particles. In a recent publication in Physical Review X, the ALICE collaboration unveiled pertinent findings regarding correlations among kaon-deuteron and proton-deuteron systems. These correlations provide insight into the fundamental forces that exist within three-body nuclear systems,
In recent years, the urgent need to reduce carbon emissions has spurred researchers to explore innovative cooling techniques that diverge from traditional methods reliant on gases and liquids. Solid-state cooling emerges as a viable alternative, harnessing the inherent properties of solid materials for refrigeration without contributing to environmental degradation. This method holds the potential to
Deep learning has emerged as a game-changing technology across various industries, including healthcare, finance, and beyond. These models, powered by neural networks, exhibit unprecedented capabilities in tasks ranging from diagnosing diseases to predicting market trends. However, as the reliance on deep learning grows, so does the necessity for substantial computational resources. Most organizations turn to
Recent advancements in nuclear physics have taken a remarkable turn with the successful synthesis of plutonium-227, a new and elusive isotope of plutonium. Led by a dedicated research team from the Institute of Modern Physics (IMP) of the Chinese Academy of Sciences (CAS), this groundbreaking work offers insights into the behavior of nuclear shells, a
The Facility for Rare Isotope Beams (FRIB) has made remarkable strides in the field of isotope research by successfully accelerating a unique beam of uranium ions. Recently, researchers at FRIB achieved an unprecedented record of 10.4 kilowatts in continuous beam power delivered to a target, marking a significant milestone in nuclear physics. This breakthrough, reported
The recent surge in research surrounding a newly characterized family of materials known as altermagnets has paved the way for exciting innovations in the fields of magnetism and materials science. These materials possess a distinctive magnetism that sets them apart from more traditional forms like ferromagnetism and antiferromagnetism. What makes altermagnets particularly intriguing is their
As society advances into an era marked by an insatiable appetite for data, conventional wireless communication methods are reaching their limits. Traditional radio frequency (RF) technologies, such as Wi-Fi and Bluetooth, are increasingly burdened by bandwidth limitations and growing wireless congestion. Users frequently encounter dropped connections, latency, and inconsistent performance, particularly in densely populated areas
Magnetic materials are a cornerstone of modern technology, heavily impacting electronics and data storage. While most individuals are familiar with typical magnets that cling to refrigerator doors, there exists a less conspicuous class of materials known as antiferromagnets. Unlike traditional magnets that exhibit distinct north and south poles, antiferromagnets operate under the principle of opposing
In a groundbreaking development in semiconductor research, scientists at UC Santa Barbara have successfully captured the first visual representation of electric charges moving across the interface of two distinct semiconductor materials. The research findings, published in the Proceedings of the National Academy of Sciences, reveal the remarkable dynamics of photocarriers, which are integral to the