Transition metal dichalcogenide heterobilayers (hBLs) have attracted significant attention in the scientific community due to their unique electronic energy band structures and potential applications in optoelectronics. One key aspect of hBLs is the moiré pattern that naturally forms between different monolayers, creating a nanoscale periodic potential that can be manipulated through twist engineering. Twist engineering
Science
Glass, a material that we often take for granted in our everyday lives, has unique properties and structures that make it an interesting subject of study. Scientists have been conducting experiments on glass in space to explore the potential for new discoveries and innovations in material science. These experiments have opened up new possibilities for
Medical imaging plays a crucial role in the diagnosis and treatment of various diseases, such as cardiovascular issues and cancer. X-ray imaging is widely used in the medical field due to its effectiveness in providing detailed images of the internal structures of the body. The development of advanced X-ray detectors is essential to improve imaging
In a groundbreaking discovery, scientists have found that a single atomic defect in a layered 2D material has the ability to retain quantum information for microseconds at room temperature. This revelation highlights the immense potential of 2D materials in advancing quantum technologies. Researchers from the Universities of Manchester and Cambridge made this significant breakthrough using
Soft robotics has been an area of growing interest due to its potential applications in various industries, from healthcare to manufacturing. In a recent paper published in Physical Review Letters, Virginia Tech physicists shed light on a groundbreaking phenomenon that could significantly enhance the performance of soft devices. The study, led by doctoral candidate Chinmay
Quantum technology has been a rapidly developing field over the past few years, with researchers constantly pushing the boundaries of what is possible. Recently, a team at the University of Bristol achieved a significant breakthrough by successfully integrating the world’s smallest quantum light detector onto a silicon chip. This groundbreaking achievement opens up a whole
Majoranas, named after an Italian theoretical physicist, are intriguing quasiparticles that hold the potential to revolutionize the field of quantum computing. These particles exhibit unique characteristics that make them ideal candidates for building next-generation quantum systems. In this article, we will delve into the world of Majorana particles, discussing their properties, potential applications, and the
Understanding diffusion in multicomponent alloys plays a crucial role in materials science and engineering. Researchers at the University of Illinois Urbana-Champaign have recently developed a new approach to modeling diffusion in solids by breaking it down into individual contributions called “kinosons.” This innovative method not only improves efficiency but also provides insights into the fundamental
Cutting-edge technologies in information processing are revolutionizing the world of telecommunications, offering a greener and more secure approach to data transmission. A recent study led by researchers from the University of Maryland (UMD) sheds light on a new device capable of processing information with minimal energy consumption, paving the way for energy-efficient and secure communications.
Dark matter remains one of the most mysterious and enigmatic aspects of the universe. Despite decades of research and numerous experiments, scientists have yet to directly detect this elusive substance. The scientific community’s current understanding of dark matter is based on its indirect effects on the motion of stars and galaxies. This leads to the