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Archive for the ‘materials’ category: Page 52

Mar 11, 2024

Chinese researchers turn diamonds into good conductors of electricity

Posted by in category: materials

Scientists used graphene, another form of carbon, but a good conductor of electricity to transform their new diamonds into conductors.

Mar 9, 2024

Korean researchers power-shame Nvidia with new neural AI chip — claim 625 times less power draw, 41 times smaller

Posted by in categories: materials, robotics/AI

A team of scientists from the Korea Advanced Institute of Science and Technology (KAIST) detailed their ‘Complementary-Transformer’ AI chip during the recent 2024 International Solid-State Circuits Conference (ISSCC). The new C-Transformer chip is claimed to be the world’s first ultra-low power AI accelerator chip capable of large language model (LLM) processing.

In a press release, the researchers power-shame Nvidia, claiming that the C-Transformer uses 625 times less power and is 41x smaller than the green team’s A100 Tensor Core GPU. It also reveals that the Samsung fabbed chip’s achievements largely stem from refined neuromorphic computing technology.

Though we are told that the KAIST C-Transformer chip can do the same LLM processing tasks as one of Nvidia’s beefy A100 GPUs, none of the press nor conference materials we have provided any direct comparative performance metrics. That’s a significant statistic, conspicuous by its absence, and the cynical would probably surmise that a performance comparison doesn’t do the C-Transformer any favors.

Mar 9, 2024

How water guides the assembly of collagen, the building block of all humans

Posted by in categories: biotech/medical, materials

Water determines life: humans are three-quarters water. An international research team led by the University of Amsterdam (UvA) has now discovered how water also determines the structure of the material that holds us together: collagen.

In a paper published in PNAS, the researchers elucidate the role of water in the molecular self-assembly of . They show that by replacing water with its ‘twin molecule’ heavy water (D2O), one can ‘tune’ the interaction between collagen molecules, and thus influence the process of collagen self-assembly. The findings will help to better understand the tissue failures resulting from heritable collagen-related diseases, such as brittle bone disease (osteogenesis imperfecta).

As lead author Dr. Giulia Giubertoni of the UvA’s Van ‘t Hoff Institute for Molecular Sciences (HIMS) puts it, “In studying these and other collagen diseases, many researchers, including myself, … have always missed an important part of the puzzle, and the possibility that tissue failure might be partly due to water-collagen interaction was not taken very seriously. We now show that perturbing the water layer around the , even very slightly, has dramatic effects on collagen assembly.”

Mar 9, 2024

Toyota’s new soft humanoid picks things up with its whole body

Posted by in categories: materials, robotics/AI

Most humanoid robots pick things up with their hands – but that’s not how we humans do it, particularly when we’re carrying something bulky. We use our chests, hips and arms as well – and that’s the idea behind Toyota’s new soft robot.

Punyo, as it’s called, is a torso-up humanoid research platform. First and foremost, it’s adorably Japanese, with a cute and approachable looking face and a cuddly, husky look reminiscent of the Baymax robot from Disney’s Big Hero 6. Adding to the cuddle factor, he appears to be wearing a big, cosy-looking sweater.

Continue reading “Toyota’s new soft humanoid picks things up with its whole body” »

Mar 9, 2024

New ‘Water Batteries’ Are Cheaper, Recyclable, And Won’t Explode

Posted by in categories: chemistry, materials

Water and electronics don’t usually mix, but as it turns out, batteries could benefit from some H2O.

By replacing the hazardous chemical electrolytes used in commercial batteries with water, scientists have developed a recyclable ‘water battery’ – and solved key issues with the emerging technology, which could be a safer and greener alternative.

Continue reading “New ‘Water Batteries’ Are Cheaper, Recyclable, And Won’t Explode” »

Mar 9, 2024

Turning skin cells into limb cells sets the stage for regenerative therapy

Posted by in categories: biotech/medical, materials

In a collaborative study, researchers from Kyushu University and Harvard Medical School have identified proteins that can turn or “reprogram” fibroblasts—the most commonly found cells in skin and connective tissue—into cells with similar properties to limb progenitor cells. Publishing in Developmental Cell, the researchers’ findings have enhanced our understanding of limb development and have set the stage for regenerative therapy in the future.

Globally, close to 60 million people are living with . Amputations can result from various medical conditions such as tumors, infections, and birth defects, or due to trauma from industrial accidents, traffic accidents, and natural disasters such as earthquakes. People with limb injuries often rely on and metal prostheses, but many researchers are studying the process of limb development, with the aim of bringing regenerative therapy, or natural tissue replacement, one step closer as a potential treatment.

“During limb development in the embryo, limb cells in the limb bud give rise to most of the different limb tissues, such as bone, muscle, cartilage and tendon. It’s therefore important to establish an easy and accessible way of making these cells,” explains Dr. Yuji Atsuta, lead researcher who began tackling this project at Harvard Medical School and continues it as a lecturer at Kyushu University’s Graduate School of Sciences.

Mar 9, 2024

Research team develops mechanoluminescent touchscreen that works underwater

Posted by in categories: materials, particle physics

Optical properties of afterglow luminescent particles (ALPs) in mechanoluminescence (ML) and mechanical quenching (MQ) have attracted great attention for diverse technological applications. A team of researchers from Pohang University of Science and Technology (POSTECH) has garnered attention by developing an optical display technology with ALPs enabling the writing and erasure of messages underwater.

The team, comprised of Professor Sei Kwang Hahn and Ph.D. candidate Seong-Jong Kim from the Department of Materials Science and Engineering at the POSTECH, uncovered a distinctive optical phenomenon in ALPs. Subsequently, they successfully created a device to implement this phenomenon. Their findings have been published in Advanced Functional Materials.

ALPs have the capability to absorb energy and release it gradually, displaying mechanoluminescence when subjected to external physical pressure and undergoing mechanical quenching where the emitted light fades away. While there has been active research on utilizing this technology for optical displays, the precise mechanism has remained elusive.

Mar 9, 2024

Evidence of phonon chirality from impurity scattering in the antiferromagnetic insulator strontium iridium oxide

Posted by in categories: materials, physics

The thermal hall effect (THE) is a physical phenomenon characterized by tiny transverse temperature differences occurring in a material when a thermal current passes through it and a perpendicular magnetic field is applied to it. This effect has been observed in a growing number of insulators, yet its underlying physics remains poorly understood.

Researchers at Université de Sherbrooke in Canada have been trying to identify the mechanism behind this effect in different materials. Their most recent paper, published in Nature Physics, specifically examined this effect in the antiferromagnetic strontium iridium oxide (Sr2IrO4).

“Our current research activity on the THE in insulators started with our discovery of a large THE in cuprate superconductors,” Louis Taillefer, co-author of the paper, told Phys.org.

Mar 9, 2024

Zero-Resistance State for a Potential High-Temperature Superconducting Nickelate

Posted by in category: materials

Last year was awash with claims that researchers had found new high-temperature superconductors. While some of those claims were quickly quashed, others are still being explored, such as the report that single crystals of the nickelate La3Ni2O7 can superconduct at up to 78 K when under a pressure of 18 gigapascals (GPa) [1]. Now experiments performed by Jinguang Cheng of the Chinese Academy of Science and colleagues strengthen the claim that this compound is indeed a superconductor [2]. If confirmed, these results would make La3Ni2O7 one of the few transition-metal compounds outside of cuprates to superconduct at temperatures above the boiling point of liquid nitrogen.

The initial report of superconductivity in La3Ni2O7 came from measurements of single crystals. Those experiments showed a sudden drop in electrical resistance at around 80 K in samples held at pressures above 14 GPa. However, the report lacked measurements of two key hallmarks of a material entering the superconducting state—its resistance falling to zero and the expulsion of external magnetic fields.

For their experiments, Cheng and his colleagues studied polycrystalline samples of La3Ni2O7 subjected to pressures of up to 18 GPa. The researchers chose polycrystalline samples over single-crystal ones, as they are significantly easier to prepare. Their resistance measurements indicated the zero-resistance state needed to confirm the presence of superconductivity. But the researchers’ attempts to detect the magnetic hallmark of superconductivity failed. Cheng says that recent unpublished results from their lab show that doping La3Ni2O7 with the lanthanide praseodymium increases the superconducting temperature to 82.5 K. In those experiments, he says, the team observed both superconducting hallmarks.

Mar 9, 2024

In Search of Muons: New Study Unveils Unexpected Behavior in Magnetic Oxides

Posted by in category: materials

Muon spectroscopy serves as a crucial experimental method for exploring the magnetic characteristics of materials. This technique involves embedding a spin-polarized muon within the crystal lattice and observing the impact of the surrounding environment on its behavior. It operates on the principle that the muon will settle into a specific location predominantly influenced by electrostatic forces, a position that can be pinpointed through the calculation of the material’s electronic structure.

But a new study led by scientists in Italy, Switzerland, UK, and Germany has found that, at least for some materials, that is not the end of the story: the muon site can change due to a well-known but previously neglected effect, magnetostriction.

Pietro Bonfà from the University of Parma, lead author of the study just published in Physical Review Letters, explains that his group and their colleagues at the University of Oxford (UK) have been using density-functional theory (DFT) simulations for at least a decade to find muon sites.

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