Stanford University researchers say they have developed a nanoscale optical device that could shift the direction of quantum communication.
Unlike today’s quantum computers that operate near absolute zero, this new approach works at room temperature.
The device entangles the spin of photons and electrons, which is essential for transmitting and processing quantum information.
Antibiotics are no longer able to treat infections as effectively as they once did because many pathogens have developed resistance to these drugs. This phenomenon, known as antimicrobial resistance (AMR), claims over a million lives worldwide each year.
Scientists have long been searching for treatments to overcome AMR, and a discovery by researchers at the University of California takes a significant step forward. The team has developed a new type of silver nanoparticle (AgNP) that is much more effective against harmful bacteria and significantly slows the rise of antibiotic resistance.
The AgNP was designed with M13 phage—a rod-shaped virus that infects E. coli bacteria—as the biological template for particle growth, resulting in a potency 30 times higher than that of commercially purchased silver nanoparticles.
Scientists have developed a revolutionary technique for creating colors that can change on command. These are structural colors that don’t rely on dyes or pigments and can be used for display signage, adaptive camouflage and smart safety labels, among other applications.
Structural colors are not created by pigments or dyes but are colorless arrangements of physical nanostructures. When light waves hit these nanostructures, they interfere with one another. Some waves cancel each other out (they are absorbed) while the rest are reflected (or scattered) back to our eyes, giving us the color we see.
Structural color systems can be engineered to reflect multiple colors from the same colorless material. This is different from pigments, which absorb light and reflect only one color—red pigments reflect red, blue pigments reflect blue and so on.
XLight, a U.S.-based startup developing an EUV light source based on a particle accelerator, on Tuesday signed a Letter of Intent (LOI) with the U.S. Department of Commerce for $150 million in proposed federal incentives under the CHIPS and Science Act. xLight came out of the blue earlier this year when it hired Pat Gelsinger, former chief executive of Intel, as executive chairman. The money, if awarded, will be used to bring xLight’s free-electron laser (FEL) based light source closer to reality once it is built in Albany and its viability is proven in practice.
“With the support from the [Department of] Commerce, our investors, and development partners, xLight is building its first free-electron laser system at the Albany Nanotech Complex, where the world’s best lithography capabilities will enable the research and development that will define the future of chip manufacturing,” said Nicholas Kelez, CEO and CTO of xLight.
At European XFEL, researchers have observed in detail how the vital iron protein ferritin makes its way in highly dense environments—with implications for medicine and nanotechnology.
Inside biological cells, there is a dense crowd where millions of proteins move side by side, bump into each other or temporarily accumulate. At the same time, these proteins often have to fulfill important tasks at short notice. How exactly the proteins move in this confined space has been difficult to track until now.
An international research team led by Anita Girelli and Fivos Perakis, both from Stockholm University, has now used the European XFEL X-ray laser in Schenefeld near Hamburg to take a closer look at these movements—and discovered a surprising pattern. The results are published in Nature Communications.
A tiny device that entangles light and electrons without super-cooling could revolutionize quantum tech in cryptography, computing, and AI.
Present-day quantum computers are big, expensive, and impractical, operating at temperatures near-459 degrees Fahrenheit, or “absolute zero.” In a new paper, however, materials scientists at Stanford University introduce a new nanoscale optical device that works at room temperature to entangle the spin of photons (particles of light) and electrons to achieve quantum communication—an approach that uses the laws of quantum physics to transmit and process data. The technology could usher in a new era of low-cost, low-energy quantum components able to communicate over great distances.
“The material in question is not really new, but the way we use it is,” says Jennifer Dionne, a professor of materials science and engineering and senior author of the paper just published in Nature Communications describing the novel device. “It provides a very versatile, stable spin connection between electrons and photons that is the theoretical basis of quantum communication. Typically, however, the electrons lose their spin too quickly to be useful.”
DNA nano machine year 2023.
An autonomous DNA-origami nanomachine powered by the chemical energy of DNA-templated RNA-transcription-consuming nucleoside triphosphates as fuel performs rhythmic pulsations is demonstrated. In combination with a passive follower, the nanomachine acts as a mechanical driver with molecular precision.
Electrotherapy using injectable nanoparticles delivered directly into the tumor could pave the way for new treatment options for glioblastoma, according to a new study from Lund University in Sweden.
Glioblastoma is the most common and most aggressive form of brain tumor among adults. Even with intensive treatment, the average survival period is 15 months. The tumor has a high genetic variation with multiple mutations, which often makes it resistant to radiation therapy, chemotherapy and many targeted drugs. The prognosis for glioblastoma has not improved over the past few decades despite extensive research.