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Category: nanotechnology

Tiny reconfigurable robots can help manage carbon dioxide levels in confined spaces

Vehicles and buildings designed to enable survival in extreme environments, such as spacecraft, submarines and sealed shelters, heavily rely on systems for the management of carbon dioxide (CO2). These are technologies that can remove and release CO2, ensuring that the air remains breathable for a long time.

Most existing systems for the capture and release of CO2 consume a lot of energy, as they rely on materials that need to be heated to high temperatures to release the gas again after capturing it. Some engineers have thus been trying to devise more energy-efficient methods to manage CO2 in confined spaces.

Researchers at Guangxi University in China have developed new reconfigurable micro/nano-robots that can reversibly capture CO2 at significantly lower temperatures than currently used carbon management systems.

Nanoscale ‘Bragg gratings’ on photonic chips suppress noise in laser light

Researchers at the University of Sydney have cracked a long-standing problem in microchip-scale lasers by carving tiny “speed bumps” into the devices’ optical cavity in their quest to produce exceptionally “clean” light. This exquisitely narrow spectrum light could be used in future quantum computers, advanced navigation systems, ultra-fast communications networks and precision sensors.

In a new study published in APL Photonics, the team shows how to eliminate a critical source of noise in Brillouin lasers, a special class of light source known for its extraordinary purity, producing an ultranarrow spectrum that is almost a perfect single wavelength (or color) of light.

Light produced from sources like lightbulbs have a broad wavelength spectrum and are fine for everyday use but are too “noisy” for precision scientific purposes, where lasers are needed.

Physicists generate hybrid spin-sound waves, expanding options for 6G implementation

Acoustic frequency filters, which convert electrical signals into miniaturized sound waves, separate the different frequency bands for mobile communications, Wi-Fi, and GPS in smartphones. Physicists at RPTU have now shown that such miniaturized sound waves can couple strongly with spin waves in yttrium iron garnet. This results in novel hybrid spin-sound waves in the gigahertz frequency range.

The use of such nanoscale hybrid spin-sound waves provides a pathway for agile frequency filters for the upcoming 6G mobile communications generation. The fundamental study by the RPTU researchers has been published in the journal Nature Communications.

Surface acoustic waves (SAWs) are ubiquitous. They unleash destructive power in the form of earthquake waves but are also at the heart of miniaturized frequency filters that are used billions of times for GHz-frequency mobile communication in smartphones.

Nanowire platform reveals elusive astrocytes in their natural state

Scientists have engineered a nanowire platform that mimics brain tissue to study astrocytes, the star-shaped cells critical for brain health, for the first time in their natural state.

Astrocytes are the brain’s most abundant and mysterious cells, responsible for regulating communication between neurons and helping to maintain the blood-brain barrier. They are also highly dynamic shape-shifters, something they do not do on typical petri dishes, leaving major gaps in our understanding of how they operate.

“Frustratingly, little is known about the stunning diversity of astrocyte morphology and we also don’t know much about the molecular machinery behind these shape shifts,” said co-senior author Ishan Barman, a Johns Hopkins University bioengineer. “They won’t take on these shapes on glass, so the question for us was how do we replicate the in vivo shape but in vitro?”

DNA transcription is a tightly choreographed event: How RNA polymerase II regulates the dance

Life’s instructions are written in DNA, but it is the enzyme RNA polymerase II (Pol II) that reads the script, transcribing RNA in eukaryotic cells and eventually giving rise to proteins. Scientists know that Pol II must advance down the gene in perfect sync with other biological processes; aberrations in the movement of this enzyme have been linked to cancer and aging. But technical hurdles prevented them from precisely determining how this important molecular machine moves along DNA, and what governs its pauses and accelerations.

A new study fills in many of those knowledge gaps. In a paper published in Nature Structural & Molecular Biology, researchers used a single-molecule platform to watch individual mammalian transcription complexes in action. The result is a clear view of how this molecular engine accelerates, pauses, and shifts gears as it transcribes genetic information.

“What’s really striking is how this machine functions almost like a finely tuned automobile,” says Shixin Liu, head of the Laboratory of Nanoscale Biophysics and Biochemistry. “It has the equivalent of multiple gears, or speed modes, each controlled by the binding of different regulatory proteins. We figured out, for the first time, how each gear is controlled.”

Sensor-integrated food wrapper can facilitate real-time, non-destructive detection of nutritional components

Food quality and safety are crucial. However, conventional food-monitoring methods, including ribotyping and polymerase chain reaction, tend to be destructive and lengthy. These shortcomings limit their potential for broad applications. In this regard, surface-enhanced Raman scattering (SERS) sensing, with real-time, non-destructive, and high sensitivity capabilities, is a highly promising alternative.

In a new breakthrough, a team of researchers, led by Associate Professor Ji-Hwan Ha from the Department of Mechanical Engineering, Hanbat National University, Republic of Korea, has developed a two-in-one nanostructured SERS sensor integrated into a stretchable and antimicrobial wrapper (NSSAW) that not only monitors food directly on the surface but also actively preserves it.

Their novel findings are published in the journal Small.

New light, strong material developed, withstands 932°F temperature

Researchers have developed very light and extremely strong material that can withstand extreme heat. The material could be useful for aerospace and other high-performance industries.

Developed by researchers from University of Toronto Engineering, the material can withstand temperatures up to 932°F (500° C).

The new composite material is made of various metallic alloys and nanoscale precipitates, and has a structure that mimics that of reinforced concrete, but on a microscopic scale.

Consciousness as the foundation: New theory addresses nature of reality

Consciousness is fundamental; only thereafter do time, space and matter arise. This is the starting point for a new theoretical model of the nature of reality, presented by Maria Strømme, Professor of Materials Science at Uppsala University, in AIP Advances. The article has been selected as the best paper of the issue and featured on the cover.

Strømme, who normally conducts research in nanotechnology, here takes a major leap from the smallest scales to the very largest—and proposes an entirely new theory of the origin of the universe. The article presents a framework in which consciousness is not viewed as a byproduct of brain activity, but as a fundamental field underlying everything we experience—matter, space, time, and life itself.

Electric Fields Steer Nanoparticles for Targeted Drug Delivery

Researchers discovered a new way to independently tune a nanoparticle’s speed and direction using different strength electric fields.

The new method could lead to better drug delivery technologies.

Read more.

A new method using a combination of strong and weak electric fields to change nanoparticle speed and direction could improve drug delivery and purification systems.

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