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Category: nanotechnology

Low-power, flexible radio-frequency transistors break 100 GHz barrier

Over the past decades, electronics engineers worldwide have been trying to develop devices that could enable even faster communications between devices, all while consuming less energy. To meet the demands of the sixth generation (6G) of wireless communication technology, these devices should operate at frequencies above 100 gigahertz (GHz).

So far, developing flexible electronic components that can operate at these high frequencies while consuming little power has proved challenging. One promising approach for fabricating these devices entails the use of carbon nanotubes (CNTs), extremely thin and cylindrical structures with advantageous electrical and thermal properties.

Researchers at Peking University and Stanford University recently developed new flexible and low-power CNT-based transistors that operate at frequencies above 100 GHz. These transistors, presented in a paper published in Nature Electronics, could potentially help to speed up communications between future smartphones, sensors, wearable devices, and other flexible devices.

Single-step 8-9x expansion reveals nanoscale centrioles without electron microscopy

In a study published in ACS Nano, researchers from National Taiwan University report a new expansion microscopy strategy termed high-fold homogeneous expansion microscopy (hiHomoExM), capable of achieving approximately 8–9× isotropic expansion in a single expansion step while preserving delicate ultrastructural organization.

Expansion microscopy works by embedding biological samples within a swellable polymer hydrogel. Following chemical processing, the hydrogel expands uniformly in water, physically separating biomolecules and effectively increasing the spatial resolution achievable by conventional light microscopes.

“To achieve nanoscale imaging faithfully, both high expansion and homogeneous specimen preservation are essential,” explains the research team. “Nonuniform expansion can distort ultrastructural information and limit biological interpretation.”

Teaching thermodynamic laws to AI unlocks a polymer modeling challenge

For more than half a century, materials scientists have struggled with how to simulate the complexity of polymer materials. An individual chain can comprise tens of thousands of atoms, a melt or composite contains billions, and the properties engineers actually care about, such as how an adhesive grips a surface, how a self-assembling block copolymer locks into a nanostructure, or how a biopolymer film stretches without tearing, emerge only over length and time scales that forcible atomistic simulation cannot reach.

The standard workaround is coarse-graining: replacing groups of atoms with simpler mesoscopic particles so the model is fast enough to run. The catch is that this compression almost always sacrifices physics. Conventional coarse-grained polymer models can usually reproduce equilibrium structure or large-scale dynamics, but rarely both, and they routinely fail to capture the entropic and viscous forces that govern how polymers actually flow, relax, and dissipate energy. Those are the forces that dictate mechanical performance, and they are the forces that traditional machine-learning approaches, despite their flexibility, also tend to break.

A research paper recently published in Proceedings of the National Academy of Sciences introduces a new machine-learning framework that lets coarse-grained models achieve both at once. A team from Carnegie Mellon University and the University of Pennsylvania has built an AI architecture that learns coarse-grained dynamics directly from data, whether simulated or experimental, while being mathematically incapable of violating the laws of thermodynamics.

New three‑dimensional magnetic structure discovered with laser light

Flashes of femtosecond laser light, lasting just a few trillionths of a second, have made it possible to observe new magnetic structures for the first time. By using light as a remote control, researchers were able to switch magnetism into previously unseen three-dimensional states at the nanoscale.

Magnetism is often imagined as something simple, pointing in one direction or another. At very small scales, however, magnetism can behave in far more complex ways. Magnetism originates from a quantum property of electrons known as spin, which can be thought of as a tiny internal compass carried by each electron. When many spins interact inside a solid material, they can organize into stable patterns.

Gold-coated optical fiber rapidly gathers microscopic targets for faster, more sensitive detection

Osaka Metropolitan University researchers have developed a light-driven technique that quickly amasses thousands of bacteria into a single spot, boosting detection speed and sensitivity. Their approach paves the way for earlier diagnosis of disease. The study is published in Communications Physics.

Many harmful bacteria, such as E. coli O157, can trigger severe ailments even at very low concentrations. Rapid detection of trace quantities of bacteria is essential to facilitate early diagnosis and prevent disease. The technique could also identify nanoparticles and other micro-and nanoscale entities that are also affecting the immune system and making the disease worse.

“Many conventional techniques are time consuming, require complex instrumentation, or are limited to collecting targets only near a surface or within a narrow focal region,” said Takuya Iida, professor at the Graduate School of Science and Research Institute for Light-induced Acceleration System (RILACS) at Osaka Metropolitan University and lead author of the study.

The quantum key to seeing through chaos

Researchers from the Institut des NanoSciences de Paris, the Kastler Brossel Laboratory and the University of Glasgow have developed an innovative method that renders a scattering medium transparent solely for information carried by entangled photon pairs, while the same medium remains completely opaque to classical light.

Their works are published in the journals Optica (optimization) and Nature Physics (selective image transmission).

Faithfully transmitting spatial information, such as the image of an object, is a major challenge in modern optics. However, this task becomes complex as soon as light travels through disordered media, such as biological tissues, atmospheric turbulence, or multimode optical fibers. In these environments, scattering scrambles the information, making the final image completely unreadable.

Researchers measure giant light-conversion effect in chiral carbon nanotubes

A sheet of twisted carbon nanotubes has revealed a hidden talent scientists suspected for decades but had never managed to measure.

Researchers at Rice University have created large, highly ordered films of chiral carbon nanotubes (CNTs), hollow cylinders of carbon atoms with either a left-or a right-handed twist. Measurements showed the crystalline films can convert the color of light at a rate two to three orders of magnitude greater than conventional materials.

The findings, reported in a study published in ACS Nano, confirm a long-standing theoretical prediction and point toward a future in which ultrathin carbon nanotube films could help power faster optical communications, flexible photonic chips and light-based computing systems that today exist mostly as prototypes.

Glucose nanoparticles help CBD cross the blood-brain barrier

Breakthrough in brain medicine: a new way to deliver CBD!

Cannabidiol (CBD) has incredible potential to fight brain inflammation, but it has always faced a major roadblock: it struggles to dissolve and cross the blood-brain barrier. Researchers have just developed an ingenious solution using glucose-coated nanoparticles to get CBD exactly where it needs to go.

Here’s why it’s a game-changer: 🔬 Sneaky Delivery: The glucose coating helps the particles “hitch a ride” on the brain’s natural glucose transporters, successfully smuggling the CBD across the blood-brain barrier. 🎯 Smart Release: Once inside the brain, the nanoparticles target immune cells (microglia) and only release the CBD when they detect the chemical stress of active inflammation. 🐁 Promising Results: In mouse models of Parkinson’s disease and depression, this new delivery method drastically reduced inflammation, protected neurons, and improved behavioral recovery compared to standard CBD.

This targeted approach could be a massive step forward in treating chronic neuroinflammatory diseases! 🧬✨

Studty.

Glucose-coated nanoparticles carry CBD across the blood-brain barrier, trigger release in inflamed tissue, and reduce neuroinflammatory signs in mice.

Continue reading “Glucose nanoparticles help CBD cross the blood-brain barrier” | >

Tritium-infused graphene could sharpen the hunt for neutrino mass

While neutrinos are some of the most abundant particles in the universe, they remain among the least understood. One of the biggest puzzles is their mass: although experiments have shown that neutrinos must have some mass, pinning down exactly how much has proven extraordinarily difficult.

Now, a team of physicists led by Valentina Tozzini of the Institute of Nanoscience in Pisa have published new theoretical calculations in Physical Review C, suggesting that tritium-infused graphene could give future experiments a decisive edge in measuring neutrino masses with unprecedented precision.

The “impossible” LED that could change everything

Scientists at the University of Cambridge have achieved what was once considered impossible by electrically powering insulating nanoparticles to create a completely new kind of LED. Using tiny organic “molecular antennas,” the team found a way to funnel energy into materials that normally cannot conduct electricity, producing ultra pure near infrared light with remarkable efficiency.

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