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A Korean research team has succeeded in securing a basic technology for further improving the completeness level of neuromorphic devices. Their paper is published in the journal Nature Communications.

Researchers from the Korea Research Institute of Standards and Science observed the fine structure of the magnon, which is attracting attention as a key material for neuromorphic devices. As areas that are approximately 1,000 times finer than before were observed successfully, it is expected that the results will enable the design of more sophisticated neuromorphic devices.

Neuromorphic devices are next-generation semiconductors designed to mimic the structure of the human brain. They process information by mimicking the way neurons generate signals and transmit them to other neurons through synapses.

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A research team from the University of Science and Technology of China has demonstrated the ability to electrically manipulate the spin filling sequence in a bilayer graphene (BLG) quantum dot (QD). This achievement, published in Physical Review Letters, showcases the potential to control the spin degree of freedom in BLG, a material with promising applications in quantum computing and advanced electronics.

BLG has drawn extensive attention in recent years due to its . When an out-of-plane electric field is applied, it can generate a tunable band gap. Moreover, the trigonal warping effect, caused by the skew interlayer coupling, gives rise to additional minivalley degeneracy, greatly influencing the behavior of charge carriers. Quantum dot devices, which can precisely control the number of charge carriers, have become a crucial tool for studying these phenomena at the single-particle level.

The research team delved into the intricate dynamics of electron shell structures within quantum dot, focusing on how these structures can be manipulated through the trigonal warping effect, a unique feature of bilayer graphene. They employed a highly tunable quantum dot device, which provided the means to control the electron filling sequence. They began by applying a small perpendicular electric field, observing that the s-shell filled with four electrons, two with spin-up and two with spin-down, each from opposite valleys.

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Researchers at the University of Bristol have made a breakthrough in the development of “life-like” synthetic materials which are able to move by themselves like worms.

Scientists have been investigating a new class of materials called “active matter,” which could be used for various applications from to .

Compared to inanimate matter—the sort of motionless materials we come across in our lives every day, such as plastic and wood—active matter can show fascinating life-like behavior.

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Ripples, like ones produced by raindrops falling in a puddle, are also called capillary waves. Studied since antiquity, they have garnered considerable interest in modern science due to their ability to reveal information about the medium on which they travel. This makes them particularly valuable for studying soft and biological matter in microfluidic applications, which focus on how fluids behave in microscopic environments.

Now physicists and from Aalto University’s Department of Neuroscience and Biomedical Engineering and Department of Applied Physics have unearthed new characteristics of capillary waves, setting a record for their speed while doing so.

The paper is published in Nature Communications.

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Three and a half kilometers beneath the Mediterranean Sea, around 80km off the coast of Sicily, lies half of a very unusual telescope called KM3NeT.

The enormous device is still under construction, but today the telescope’s scientific team announced they have already detected a particle from with a staggering amount of energy.

In fact, as the team report in Nature, they found the most energetic neutrino anyone has ever seen—and it represents a tremendous leap forward in exploring the uncharted waters of the extreme universe.

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From high-speed communication to quantum computing and sensing, the detection, transmission, and manipulation of light (photons) have transformed modern electronics. Central to these systems are photon detectors, which detect and measure photons.

One notable type is the superconducting nanowire single-photon detector (SNSPD). SNSPDs utilize ultra-thin superconducting wires that quickly transition from a superconducting state to a resistive state when a photon strikes, allowing for ultra-fast detection.

The wires in these detectors are arranged in a Peano arced-fractal pattern, which remains consistent across various scales. This unique design enables the detector to detect photons regardless of their direction or polarization (the orientation of the photon’s electric field). Due to these advantages, arced-fractal SNSPDs (AF SNSPDs) are crucial in applications such as light detection and ranging, quantum computing, and quantum communication.

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Flock of Meese’s engine is a fully custom-built, Minecraft-inspired engine created to run on older consoles like the Dreamcast, GameCube, and Wii. While it might look just like a Minecraft clone for now, the goal is to replicate the mechanics of Minecraft Beta 1.7.3 and then evolve into an original block-based game that surpasses it in both gameplay and visual fidelity, showcasing the technical capabilities of this engine.

Meese specifically chose the Dreamcast because it’s barely capable enough to run an open-world voxel game. This challenge sparked a lot of creativity in performance optimization, and the result was a major success: despite having only 16 MB of main RAM, Dreamcast already runs Meese’s engine at 30 FPS, while the GameCube port achieves a smooth 60 FPS.

Why would someone build an engine for these old consoles? It seems like a project of passion, similar to how people continue to port DOOM to different devices, testing their programming skills to the limit and exploring just how far classic games can be pushed. Once released, you’ll have the chance to put your 20-year-old consoles to work with this game, or you can choose to play it via a PC port. According to Meese, there will likely be a distinction between the modern PC version and the retro console versions, as he wants the PC to fully take advantage of newer hardware.

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Researchers have made a breakthrough in THz frequency conversion using graphene.

Graphene is an allotrope of carbon in the form of a single layer of atoms in a two-dimensional hexagonal lattice in which one atom forms each vertex. It is the basic structural element of other allotropes of carbon, including graphite, charcoal, carbon nanotubes, and fullerenes. In proportion to its thickness, it is about 100 times stronger than the strongest steel.

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The first step in this process is determining where in the brain the BCI should record from to decode someone’s intended speech.

Currently, BCI devices are only used on individuals with paralysis from ALS or stroke in the brainstem, which leaves them unable to move or communicate. In these patients, BCIs record signals from the frontal lobe. But Broca’s aphasia, which most often affects people after a stroke or brain tumor, results from damage to the frontal lobe of the brain, where speech production and parts of language are processed. So, to help patients with Broca’s aphasia, scientists would likely need to record signals from other areas of the brain.

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Synthetic biologists from Yale successfully rewrote the genetic code of an organism—a novel genomically recoded organism (GRO) with a single stop codon—using a cellular platform they developed that enables the production of new classes of synthetic proteins. Researchers say these synthetic proteins offer the promise of innumerable medical and industrial applications that can benefit society and human health.

A new study published in the journal Nature describes the creation of the landmark GRO, known as “Ochre,” which fully compresses redundant (or “degenerate”) codons into a single codon. A codon is a sequence of three nucleotides in DNA

DNA, or deoxyribonucleic acid, is a molecule composed of two long strands of nucleotides that coil around each other to form a double helix. It is the hereditary material in humans and almost all other organisms that carries genetic instructions for development, functioning, growth, and reproduction. Nearly every cell in a person’s body has the same DNA. Most DNA is located in the cell nucleus (where it is called nuclear DNA), but a small amount of DNA can also be found in the mitochondria (where it is called mitochondrial DNA or mtDNA).

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