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Archive for the ‘computing’ category: Page 133

Jan 25, 2024

Framework Laptop 16 review: the Franken-notebook

Posted by in category: computing

The Framework Laptop 16 is the most customizable laptop we’ve ever seen, with tons of input and port options, and the promise of upgradable graphics. It has a bright screen and solid battery life, but it’s expensive, and you could get something with more performance for the price.


Framework introduces replaceable graphics for the first time, along with customizable keyboards and other accessories.

Jan 25, 2024

Innovative silicon nanochip can reprogram biological tissue in living body

Posted by in categories: biotech/medical, computing, engineering, life extension, neuroscience, singularity

Year 2021 Biocomputing is the future for the biological singularity because we could control all inputs and outputs of our bodies even evolve them eventually.


A silicon device that can change skin tissue into blood vessels and nerve cells has advanced from prototype to standardized fabrication, meaning it can now be made in a consistent, reproducible way. As reported in Nature Protocols, this work, developed by researchers at the Indiana University School of Medicine, takes the device one step closer to potential use as a treatment for people with a variety of health concerns.

The technology, called tissue nanotransfection, is a non-invasive nanochip device that can reprogram tissue function by applying a harmless electric spark to deliver specific genes in a fraction of a second. In laboratory studies, the device successfully converted into to repair a badly injured leg. The technology is currently being used to reprogram tissue for different kinds of therapies, such as repairing caused by stroke or preventing and reversing nerve damage caused by diabetes.

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Jan 25, 2024

Faster Than Ever: Scientists Push Compressed Sensing to Real-Time Edge Applications

Posted by in category: computing

A team of researchers headed by Professor Sun Zhong at Peking University recently unveiled an analog hardware approach for real-time compressed sensing recovery. Their findings have been documented in a paper recently published in Science Advances.

In this work, a design based on a resistive memory (also known as memristor) array for performing instantaneous matrix-matrix-vector multiplication (MMVM) is first introduced. Based on this module, then an analog matrix computing circuit that solves compressed sensing (CS) recovery in one step (within a few microseconds) is disclosed.

Jan 25, 2024

Kenya strikes large deposits of mineral used in phones, laptops

Posted by in categories: computing, economics, mobile phones

Kenya has announced that the precious coltan mineral, which is used in the manufacture of cell phones, laptops and other communication gadgets has been found in the country.

Mining and Blue Economy Cabinet Secretary (CS) Salim Mvurya said on Wednesday that adequate deposits of coltan have been found in six counties.

The rare metallic mineral, mostly found in the eastern part of the Democratic Republic of Congo (DRC), is mainly used for the production of electronic goods of mass consumption, such as mobile phones, laptops and videogame consoles, and its discovery in Kenya is set to raise the country’s profile as a mineral exporter.

Jan 24, 2024

Study offers new insights into understanding and controlling tunneling dynamics in complex molecules

Posted by in categories: biological, chemistry, computing, quantum physics

Tunneling is one of most fundamental processes in quantum mechanics, where the wave packet could traverse a classically insurmountable energy barrier with a certain probability.

On the , effects play an important role in , such as accelerating enzyme catalysis, prompting spontaneous mutations in DNA and triggering olfactory signaling cascades.

Photoelectron tunneling is a key process in light-induced , charge and energy transfer and radiation emission. The size of optoelectronic chips and other devices has been close to the sub-nanometer atomic scale, and the quantum tunneling effects between different channels would be significantly enhanced.

Jan 24, 2024

What coffee with cream can teach us about quantum physics

Posted by in categories: computing, quantum physics

Add a dash of creamer to your morning coffee, and clouds of white liquid will swirl around your cup. But give it a few seconds, and those swirls will disappear, leaving you with an ordinary mug of brown liquid.

Something similar happens in quantum computer chips—devices that tap into the strange properties of the universe at its smallest scales—where information can quickly jumble up, limiting the memory capabilities of these tools.

That doesn’t have to be the case, said Rahul Nandkishore, associate professor of physics at the University of Colorado Boulder.

Jan 24, 2024

Manipulated hafnia paves the way for next-gen memory devices

Posted by in categories: computing, materials

Scientists and engineers have been pushing for the past decade to leverage an elusive ferroelectric material called hafnium oxide, or hafnia, to usher in the next generation of computing memory.


Scientists outline new processes for leveraging the ferroelectric features of hafnia with the aim of enhancing high-performance computing.

Jan 24, 2024

Leveling Up in Life Sciences: Unleashing the Power of Computational Biology with Wolfram Language

Posted by in categories: biological, computing

Explore life sciences with Wolfram Language Demonstrations, Function Repository, Q&As, Community posts and more, at any skill level. Research computational biology and find your computational X.

Jan 24, 2024

Intel’s next-gen Arrow Lake CPUs might come without hyperthreaded cores — leak points to 24 CPU cores, DDR5-6400 support, and a new 800-series chipset

Posted by in category: computing

According to a leak, Arrow Lake-S processors will not increase core count but will require a new chipset.

Jan 24, 2024

Long-Range Resonances Slow Light in a Photonic Material

Posted by in categories: computing, nanotechnology, particle physics

Light can behave in strange ways when it interacts with materials. For example, in a photonic material that consists of periodic arrangements of nanoscale optical cavities, light can slow to a crawl or even stop altogether. Theorists have explained this phenomenon for some of these photonic “metacrystals” using the simplifying assumption that the light in each cavity interacts only with the light in its nearest neighbor cavities. But recent observations of photonic metacrystals with larger unit cells suggest that longer-range interactions should also be considered. Now Thanh Xuan Hoang at the Agency for Science, Technology and Research in Singapore and collaborators have theoretically confirmed the importance of long-range interactions for slowing or stopping light in a one-dimensional photonic metacrystal [1]. The team says that the finding could be used to help researchers design nanoparticle arrays for analog image processing and optical computing.

For their study, Hoang and his collaborators modeled the light–matter interactions within a row of identical dielectric nanoparticles whose diameters were similar to the wavelength of the light. Such a system is relatively tractable with precise solutions, making it a useful tool for investigating the long-range effects hinted at by recent experiments.

When the researchers extended their one-dimensional system to hundreds of nanoparticles, they found that they could collectively excite the particles by oscillating a nearby electric dipole. The resulting system displayed a resonant state that slowed a specific wavelength of light. This outcome occurred only when long-range interactions between particles were permitted. Hoang likens the dipolar emitter to the conductor of an orchestra and the particles to musicians. The nanoparticles harmonize under the conductor’s direction to create a cohesive piece, he says.