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A new study by Rice University physicist Qimiao Si unravels the enigmatic behaviors of quantum critical metals—materials that defy conventional physics at low temperatures. Published in Nature Physics Dec. 9, the research examines quantum critical points (QCPs), where materials teeter on the edge between two distinct phases, such as magnetism and nonmagnetism. The findings illuminate the peculiarities of these metals and provide a deeper understanding of high-temperature superconductors, which conduct electricity without resistance at relatively high temperatures.
Key to this study is quantum criticality, a delicate state where the material becomes ultrasensitive to quantum fluctuations—microscopic disturbances that alter electron behavior. While ordinary metals obey well-established principles, quantum critical metals defy these norms, exhibiting strange and collective properties that have long puzzled scientists. Physicists call such systems “strange metals.”
“Our work dives into how quasiparticles lose their identity in strange metals at these quantum critical points, which leads to unique properties that defy traditional theories,” said Si, the Harry C. and Olga K. Wiess Professor of Physics and Astronomy and director of Rice’s Extreme Quantum Materials Alliance.
Intel Foundry has showcased “breakthrough” developments in the realm of transistor and packaging technologies, revealing material and silicon innovation.
Intel Foundry Showcases “Subtractive Ruthenium” & New Transistor Technologies To Ensure Node Scalability
[Press Release]: Today at the IEEE International Electron Devices Meeting (IEDM) 2024, Intel Foundry unveiled breakthroughs to help drive the semiconductor industry forward into the next decade and beyond. Intel Foundry showcased new material advancements that help improve interconnections within a chip, resulting in up to 25% capacitance by using subtractive ruthenium.
MXenes in grooved plastic create durable, heat-tolerant films that twist light beams.
A team of researchers at the University of Michigan employed MXenes, a type of ceramic-like material derived from industrial waste materials to develop heat-tolerant films capable of twisting light beams.
The MXenes were integrated into plastic sheets with microscopic grooves to create sturdy, heat-tolerant films capable of twisting light beams.
Continue reading “Ceramic-like material help craft heat-tolerant films from waste” »
Discover how SpaceX is achieving the impossible: producing one Raptor engine every 24 hours. From rapid iteration and innovative materials to the McGregor testing facility, learn what makes this engine the muscle behind the Starship program.
Ingestible devices are often used to study and treat hard-to-reach tissues in the body. Swallowed in pill form, these capsules can pass through the digestive tract, snapping photos or delivering drugs.
While in their simplest form, these devices are passively transported through the gut, there are a wide range of applications where you may want a device to attach to the tissue or other flexible materials. A rich history of biologically inspired solutions exist to address this need, ranging from cocklebur-inspired Velcro to slug-inspired medical adhesives, but the creation of on-demand and reversible attachment mechanisms that can be incorporated into millimeter-scale devices for biomedical sensing and diagnostics remains a challenge.
A new interdisciplinary effort led by Robert Wood, the Harry Lewis and Marlyn McGrath Professor of Engineering and Applied Sciences in the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS), and James Weaver, of Harvard’s Wyss Institute, has drawn inspiration from an unexpected source: the world of parasites.
Astronomers have used the unique capabilities of NASA’s Hubble Space Telescope to peer closer than ever into the throat of an energetic monster black hole powering a quasar. A quasar is a galactic center that glows brightly as the black hole consumes material in its immediate surroundings.
The new Hubble views of the environment around the quasar show a lot of “weird things,” according to Bin Ren of the Côte d’Azur Observatory and Université Côte d’Azur in Nice, France. “We’ve got a few blobs of different sizes, and a mysterious L-shaped filamentary structure. This is all within 16,000 light-years of the black hole.”
Some of the objects could be small satellite galaxies around the black hole, and so they could offer the materials that will accrete onto the central super massive black hole, powering the bright lighthouse.
Researchers created concrete reinforced with nanocrystals that is 30 percent stronger than traditional cement.
A method that can grow a useful insulating material into exceptionally high-quality films that are just one atom thick and are suitable for industrial-scale production has been developed by an international team led by Xixiang Zhang from KAUST.
The work is published in the journal Nature Communications.
The material, called hexagonal boron nitride (hBN), is used in semiconductor devices and can also enhance the performance of other two-dimensional (2D) materials such as graphene and transition metal dichalcogenides (TMDs).
Transistors based on two-dimensional (2D) semiconductors, such as molybdenum disulfide (MoS2) and tungsten diselenide (WSe2), could outperform conventional silicon-based transistors, while also being easier to reduce in size. To perform well, these transistors need to be based on high-quality dielectric materials, which can be difficult to prepare.
Researchers at Nanyang Technological University, Nanjing University of Aeronautics and Astronautics recently introduced a new promising strategy to prepare the dielectric materials for these transistors. Their approach, outlined in a paper published in Nature Electronics, was successfully used to deposit an ultrathin and uniform native oxide of gallium Ga2O3 on the surface of MoS2.
“Traditional methods of preparing dielectric layer, such as atomic layer deposition (ALD), encounter quality problems because of the high-quality surface of 2D semiconductors without sufficient nucleation points, especially at thin thicknesses down to a few nanometers,” Kongyang Yi, first author of the paper, told Tech Xplore.
