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Archive for the ‘nanotechnology’ category: Page 164

Feb 13, 2021

Researchers hack Xbox console to develop nanoscale medical 3D printer

Posted by in categories: biotech/medical, cybercrime/malcode, nanotechnology

Researchers from the Technical University of Denmark (DTU) have repurposed a component from a Microsoft Xbox 360 to develop a high-resolution large-volume nanoscale 3D printer with various applications in the medical sector.

The team took an optical pick-up unit (OPU) component from an Xbox 360 console to replace a conventional Stereolithography (SLA) optical system, in order to drastically simplify the SLA 3D printing system. With the OPU costing less than $5, the researcher’s solution could potentially increase the affordability of such equipment by thousands of pounds.

“With our 3D printer that can print micro and nanoscale 3D objects, we are able to go from tens of micrometers in printing resolution down to hundreds of nanometers without expensive specialized components,” said DTU PhD Student Tien-Jen Chang and research team member.

Feb 11, 2021

Mechanochemical bond scission for the activation of drugs

Posted by in categories: biotech/medical, chemistry, nanotechnology

Stimuli-responsive control of drug activation can mitigate issues caused by poor drug selectivity. Now, it has been shown that mechanical force—induced by ultrasound—can be used to activate drugs in three different systems. This approach has enabled the activation of antibiotics or a cytotoxic anticancer agent from synthetic polymers, polyaptamers and nanoparticle assemblies.

Feb 8, 2021

A nano-hospital in every body

Posted by in categories: biotech/medical, nanotechnology

Nanoscale doctors curing the body from within sounds like science fiction, but for Japanese research centre COINS, it’s a serious goal.

Feb 5, 2021

Silicon anode structure generates new potential for lithium-ion batteries

Posted by in categories: materials, nanotechnology

New research conducted by the Okinawa Institute of Science and Technology Graduate University (OIST) has identified a specific building block that improves the anode in lithium-ion batteries. The unique properties of the structure, which was built using nanoparticle technology, are revealed and explained today in Communications Materials.

Feb 1, 2021

Ingenious ‘Wrinkled’ Graphene Could Be The Most Promising Water Filter Yet

Posted by in categories: nanotechnology, particle physics, transportation

Graphene continues to dazzle us with its strength and its versatility – exciting new applications are being discovered for it all the time, and now scientists have found a way of manipulating the wonder material so that it can better filter impurities out of water.

The two-dimensional material comprised of carbon atoms has been studied as a way of cleaning up water before, but the new method could offer the most promising approach yet. It’s all down to the exploitation of what are known as van der Waals gaps: the tiny spaces that appear between 2D nanomaterials when they’re layered on top of each other.

These nanochannels can be used in a variety of ways, which scientists are now exploring, but the thinness of graphene causes a problem for filtration: liquid has to spend much of its time travelling along the horizontal plane, rather than the vertical one, which would be much quicker.

Jan 30, 2021

Physicists Observe Fleeting ‘Polaron’ Quasiparticles For The First Time

Posted by in categories: nanotechnology, particle physics

Polarons are important nanoscale phenomena: a transient configuration between electrons and atoms (known as quasiparticles) that exist for only trillionths of a second.

Jan 28, 2021

Efficiently Converting Light Energy Into Surface Waves on Graphene

Posted by in categories: energy, nanotechnology, physics

Dotty graphene and doping: Whatever it takes for Russia’s record plasmonics to shine.

Physicists from MIPT and Vladimir State University, Russia, have achieved a nearly 90% efficiency converting light energy into surface waves on graphene. They relied on a laser-like energy conversion scheme and collective resonances. The paper came out in Laser & Photonics Reviews.

Manipulating light at the nanoscale is a task crucial for being able to create ultracompact devices for optical energy conversion and storage. To localize light on such a small scale, researchers convert optical radiation into so-called surface plasmon-polaritons. These SPPs are oscillations propagating along the interface between two materials with drastically different refractive indices — specifically, a metal and a dielectric or air. Depending on the materials chosen, the degree of surface wave localization varies. It is the strongest for light localized on a material only one atomic layer thick, because such 2D materials have high refractive indices.

Jan 27, 2021

Researchers use nanomaterials to make 2-D diamond clusters at room temperature

Posted by in categories: chemistry, nanotechnology

Atomically thin, 2-D hexagonal boron nitride (h-BN) is a promising material whose protean ability to undergo phase transformations to strong, super lightweight, chemically stable, oxidation-resistant films makes them ideal for protective coatings, nanotechnology thermal applications, deep-UV light emitters, and much more.

Jan 27, 2021

Tiny bio-inspired swarm robots for targeted medical interventions

Posted by in categories: biotech/medical, nanotechnology, robotics/AI

Micro-sized robots could bring a new wave of innovation in the medical field by allowing doctors to access specific regions inside the human body without the need for highly invasive procedures. Among other things, these tiny robots could be used to carry drugs, genes or other substances to specific sites inside the body, opening up new possibilities for treating different medical conditions.

Researchers at ETH Zurich and Helmholtz Institute Erlangen–Nürnberg for Renewable Energy have recently developed micro and nano-sized robots inspired by biological micro-swimmers (e.g., bacteria or spermatozoa). These , presented in a paper published in Nature Machine Intelligence, are capable of upstream motility, which essentially means that they can autonomously move in the opposite direction to that in which a fluid (e.g., blood) flows. This makes them particularly promising for intervening inside the .

“We believe that the ideas discussed in our multidisciplinary study can transform many aspects of medicine by enabling tasks such as targeted and precise delivery of drugs or genes, as well as facilitating non-invasive surgeries,” Daniel Ahmed, lead author of the recent paper, told TechXplore.

Jan 26, 2021

Researchers construct molecular nanofibers that are stronger than steel

Posted by in categories: bioengineering, biotech/medical, chemistry, nanotechnology

Self-assembly is ubiquitous in the natural world, serving as a route to form organized structures in every living organism. This phenomenon can be seen, for instance, when two strands of DNA—without any external prodding or guidance—join to form a double helix, or when large numbers of molecules combine to create membranes or other vital cellular structures. Everything goes to its rightful place without an unseen builder having to put all the pieces together, one at a time.

For the past couple of decades, scientists and engineers have been following nature’s lead, designing molecules that assemble themselves in , with the goal of making nanostructures, primarily for such as drug delivery or tissue engineering. “These small-molecule-based materials tend to degrade rather quickly,” explains Julia Ortony, assistant professor in MIT’s Department of Materials Science and Engineering (DMSE), “and they’re chemically unstable, too. The whole structure falls apart when you remove the water, particularly when any kind of external force is applied.”

She and her team, however, have designed a new class of small molecules that spontaneously assemble into nanoribbons with unprecedented strength, retaining their structure outside of water. The results of this multi-year effort, which could inspire a broad range of applications, were described on Jan. 21 in Nature Nanotechnology by Ortony and coauthors.