Quantum mechanics governs the behavior of electrons within magnetic materials, with their spins dictating the magnetic properties of the material. Now, a team of researchers from JILA, led by Margaret Murnane and Henry Kapteyn, has made a groundbreaking breakthrough in controlling these spins with exceptional precision. By harnessing the power of extreme ultraviolet high-harmonic generation
Physics
Quantum materials are hailed as the key to unlocking a future of lightning-speed and energy-efficient information systems. However, harnessing their transformative potential has proven to be a challenge. In solid materials, the vast number of atoms often masks the exotic quantum properties that electrons carry. But now, researchers at Rice University have discovered a fascinating
Researchers from the Niels Bohr Institute (NBI) have made significant progress in the development of quantum sensors, paving the way for the creation of highly sensitive monitoring devices. These quantum sensors have the potential to revolutionize various fields, including medical examinations and gravitational wave detection, by offering unprecedented accuracy and precision. Led by Professor Eugene
Microscopes have long been used to study materials by irradiating them with light or electrons. However, a research group from the Institute of Industrial Science at the University of Tokyo is challenging this traditional approach. They are pioneering a new method that leverages the faint light emitted by materials themselves, generated by heat. This innovative
When someone performs a belly flop into a swimming pool, the result is a loud splat, a huge splash, and a painful sting. But have you ever wondered why belly flops are so painful? According to Daniel Harris, an assistant professor in Brown University’s School of Engineering, the physics behind belly flops are not as
Researchers in Germany and the U.S. have made a groundbreaking discovery in the field of material physics. They have demonstrated that the magnetic state of an atomically thin material, α-RuCl3, can be controlled solely by placing it into an optical cavity. This means that the cavity vacuum fluctuations alone are enough to change the material’s
Harnessing and controlling light is essential for the advancement of technology in various fields such as energy harvesting, computation, communications, and biomedical sensing. However, the complex behavior of light poses challenges for its efficient control. In a recent study published in Nature Physics, researchers at the CUNY Graduate Center have developed a new platform that
In the realm of scientific advancements, optical tweezers have emerged as a groundbreaking technology with numerous applications in fields like cancer therapy and environmental monitoring. These devices, which utilize lasers to manipulate tiny particles such as cells and nanoparticles, were even honored with a Nobel Prize in 2018. Now, a team of scientists has taken
In the realm of unconventional computing technologies, a team of physicists has achieved a significant breakthrough in the field of room-temperature quantum fluids of light. This advancement in spatial manipulation and energy control of polariton condensates showcases the potential for high-speed, all-optical polariton logic devices, which have long been seen as the key to next-generation
Holographic imaging has long been plagued by distortions in dynamic environments, making it difficult for traditional deep learning methods to adapt. These methods often struggle because they are designed to rely on specific data conditions, which limits their ability to handle diverse scenes. However, researchers at Zhejiang University recognized this problem and set out to
Phonons, which are quasi-particles associated with sounds or lattice vibrations, have long been thought to possess negligible magnetic moments. However, a recent experiment conducted by researchers at Nanjing University and the Chinese Academy of Sciences has challenged this notion. Their study, featured in Nature Physics, has uncovered giant phonon magnetic moments in Fe2Mo3O8, a polar
Advancements in quantum computing have revolutionized the field of problem-solving, addressing challenges that were once considered insurmountable for conventional computers. Quantum computers have the potential to tackle complex problems in cryptography, pharmacology, and the study of molecular and material properties. However, the current computational capabilities of quantum computers remain limited. QUBO: Uniting Quantum and Traditional