The alignment of supermoiré lattices has long been a challenge in the field of quantum materials research. However, a team of physicists from the National University of Singapore (NUS) has recently developed a groundbreaking technique to precisely control the alignment of these lattices using a set of golden rules. This significant advancement paves the way
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Polarization is a fundamental aspect of light waves that plays a crucial role in numerous optical applications. From sunglasses and camera lenses to advanced optical communication and imaging systems, understanding and mastering the polarization of light is vital for the advancement of these technologies. However, manipulating the spatial distribution of the polarization state of an
Neutrinos, the tiny and neutrally charged particles, have long remained a challenge for particle physicists. Although they are believed to be abundant in the universe, detecting them has been difficult due to their low interaction probability with matter. However, recent breakthroughs in experimental particle physics research have led to the observation of neutrinos inside colliders
Understanding how light interacts with molecules is a crucial step in various scientific disciplines. In particular, electron dynamics, which occur at the attosecond timescale, play a fundamental role in chemical reactions and biological functions related to light-matter interaction. One aspect of electron dynamics is charge migration (CM), which involves the movement of charge within a
In a groundbreaking study, researchers from Los Alamos National Laboratory have developed a new method to generate a stream of circularly polarized single photons. This achievement has important implications for various applications in quantum information and communication. By stacking two different atomically thin materials, the team created a chiral quantum light source that can emit
Scientists from Queen Mary University of London have made a groundbreaking discovery that has the potential to revolutionize our understanding of the universe. In a study published in Science Advances, they reveal the existence of a range in which fundamental constants can vary, providing the necessary viscosity for vital life processes within and between living
Amorphous materials, such as plastic and glass, have long fascinated scientists due to their unique properties. Unlike crystalline solids, these materials don’t form orderly structures when cooled. Instead, they remain in a supercooled liquid state, flowing extremely slowly. Recently, researchers at the Department of Energy’s Lawrence Berkeley National Laboratory have made significant advancements in understanding
In a groundbreaking collaboration, a team of brilliant minds from the esteemed Ames National Laboratory and Texas A&M University has unveiled a revolutionary technique to predict metal ductility. This novel quantum-mechanics-based approach has emerged as the go-to solution for predicting ductility in materials, marking a significant breakthrough in the field of material science. With its