When ultrafast electrons are deflected, they emit light—synchrotron radiation. This light, while brilliant, is longitudinally incoherent and consists of a broad spectrum of wavelengths, making it less efficient for certain types of materials research. Monochromators have been used to select individual wavelengths from this spectrum, but at the cost of reducing radiant power significantly. Physicist
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Supersymmetry (SUSY) is a groundbreaking theory in particle physics that aims to address unresolved questions within the field. It proposes the existence of “superpartners” for all known particles, each with unique properties. For instance, the heaviest quark in the Standard Model, the top quark, would have a corresponding superpartner known as the top squark or
Titanium-sapphire (Ti:sapphire) lasers have long been revered for their unmatched performance in various cutting-edge fields such as quantum optics, spectroscopy, and neuroscience. However, the hefty price tag and bulky nature of traditional Ti:sapphire lasers have hindered their widespread adoption in the real world. Fortunately, researchers at Stanford University have made a groundbreaking advancement by developing
In a groundbreaking study published in Nature Communications, a team of scientists led by Rice University’s Qimiao Si has uncovered the potential existence of flat electronic bands at the Fermi level in quantum materials. This discovery holds immense promise for the development of new forms of quantum computing and electronic devices. Quantum materials, governed by
For decades, scientists have theorized the existence of kugelblitze, which are black holes formed by extremely high concentrations of light. These theoretical black holes were believed to play a significant role in understanding astronomical phenomena such as dark matter and were even considered as a potential power source for future spaceship engines. However, recent research
Scientific breakthroughs often occur when researchers combine seemingly unrelated concepts to push the boundaries of knowledge. Just as Maxwell’s theory of light emerged from the reciprocity of electricity and magnetism, a recent collaboration between Professor Szameit’s research group at the University of Rostock and researchers from Albert-Ludwigs-Universität Freiburg has led to a groundbreaking discovery in
In a recent study published in Physical Review Letters (PRL), researchers delved into the potential of quadratic electron-phonon coupling to boost superconductivity by forming quantum bipolarons. Electron-phonon coupling involves the interaction between electrons and vibrations in a lattice known as phonons. This interaction plays a crucial role in enabling superconductivity in certain materials by aiding
Photonic alloys, a class of materials that combine photonic crystals, have shown great potential in controlling electromagnetic wave propagation. However, a common issue with these materials is the phenomenon of light backscattering, which hinders their performance as waveguides. Finding solutions to reduce or eliminate light backscattering is crucial for advancing the practical application of photonic
The anomalous Hall effect is a phenomenon that occurs in magnetic materials, where an electric current flowing through a metal sample generates a voltage perpendicular to the magnetic field and current. This effect is typically observed in ferromagnetic materials, where electron spins are aligned. The alignment of spins leads to the manifestation of the anomalous
In a groundbreaking development, scientists have devised a novel method to capture dark matter using a specially designed 3D printed vacuum system. This innovative approach aims to detect domain walls, shedding light on the enigmatic mysteries of the cosmos. Researchers from the University of Nottingham’s School of Physics have embarked on this ambitious journey by