Articles tagged with Phases Of Matter
Researchers observed pair-density waves (PDW) intertwined with charge density wave stripes in a copper oxide material, supporting the possibility that PDW is present in all superconducting cuprates. The new technique used to detect PDW has potential for directly sighting its correlations with other phases.
EPFL physicists have found a way to visualize the whole melting process of skyrmion crystals in Cu2OSe3 by varying magnetic field. They used LTEM to record massive images and videos, demonstrating two novel phases: the skyrmion hexatic phase and the skyrmion liquid phase.
Researchers at Skoltech and Southampton University develop a fully optical approach to control couplings between polariton condensates, enabling simulation of condensed matter phases. This technology uses laser excitation patterns to generate complex polariton graphs in a scalable manner.
University of Arkansas physicists have discovered materials with higher quantum spin numbers and applied physical strain to tune magnetic states. This expands the list of potential candidates for Kitaev-type quantum spin liquids, a key step towards proving their existence.
A team of researchers has revealed a new state of matter where Cooper pairs enable electricity to flow with some resistance. This finding challenges current theories and requires further investigation. The discovery was made using a technique that involves patterning a thin-film superconductor with arrays of tiny holes.
Researchers at Ehime University discovered a molecular insulating crystal that reversibly exhibits metal-like conducting behavior under UV-irradiation. This unique property indicates the existence of other photoexcited states of matter with novel properties.
Researchers at Iowa State University have made three groundbreaking discoveries about non-equilibrium quantum phase discovery via non-thermal ultrafast quench near quantum critical points. These findings could lead to the development of new technologies such as optical computing, novel sensors and high-speed communication capabilities.
Researchers used state-of-the-art technology to investigate collective behavior of electrons in titanium and zirconium, uncovering interplay between light absorption and electronic screening. The study reveals new insights into coupled-electron dynamics, enabling ultrafast manipulation of phases of matter.
Researchers at Penn State and Argonne National Laboratory created a stable supercrystal using a burst of blue laser light. The supercrystal has a unit cell one million times larger than ordinary crystals, with properties that don't exist in equilibrium nature.
A team of researchers has discovered a long-lived new state of matter in an iron pnictide superconductor, which reveals collective behaviors that compete with superconductivity. The discovery was made using laser-induced spectroscopy techniques, allowing for real-time observation of electron pairings and fluctuations.
Researchers have developed a new platform for studying 2D magnetism, which could lead to breakthroughs in quantum computing, sensing technologies, and superconductors. The discovery of novel materials with specific functionality could also deepen our understanding of fundamental issues in condensed matter physics.
Researchers use ultra-cold neutral lithium atoms to study conductivity in a one-dimensional quantum tube. They discover an unusual state of matter that retains its insulation regardless of particle interactions, challenging conventional theories about materials.
Researchers at the University of Chicago discovered a topological wave in a randomly arranged material, defying traditional expectations. The finding offers new insights into collective motion and could have implications for electronics and optics.
Researchers have successfully created a phase of matter called a time crystal, where atoms move in a repeating pattern in time rather than space. This discovery opens up new possibilities for storing and transferring information in quantum computers.
Scientists observe a Many-Body Localized state in ultracold atoms trapped in light crystals, where interactions fail to lead to thermalization. This peculiar insulating state retains a quantum memory of its initial state, even at elevated temperatures.
Researchers discovered a distinct order in electrons during pseudogap state, present both above and below superconducting temperatures. The findings provide a clear signpost for follow-up research to uncover the nature of the pseudogap order.
Researchers have successfully observed the Efimov state in a new state of matter where three cesium atoms behave like an entangled Borromean ring. This achievement may lead to the creation of novel materials with controlled properties, revolutionizing fields such as nanotechnology.