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People who owned black-and-white television sets until the 1980s didn’t know what they were missing until they got a color TV. A similar switch could happen in the world of genomics as researchers at the Berlin Institute of Medical Systems Biology of the Max Delbrück Center (MDC-BIMSB) have developed a technique called Genome Architecture Mapping (“GAM”) to peer into the genome and see it in glorious technicolor. GAM reveals information about the genome’s spatial architecture that is invisible to scientists using solely Hi-C, a workhorse tool developed in 2009 to study DNA interactions, reports a new study in Nature Methods by the Pombo lab.

With a black-and-white TV, you can see the shapes but everything looks grey. But if you have a color TV and look at flowers, you realize that they are red, yellow and white and we were unaware of it. Similarly, there’s also information in the way the genome is folded in three-dimensions that we have not been aware of.

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Lot’s of science news, stay till the end for the climate stuff.

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Today we’ll talk about plants that use quantum mechanics, the first data from a new galaxy survey, quantum utility, online hate groups, photonic computing, the most sensitive power measurement ever, how to map a tunnel with muons, bad climate news that I don’t want to talk about, and you don’t want to hear, but that we need to talk about anyway. And of course, the telephone will ring.

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Scientists have solved a decades-long mystery on whether light can be effectively trapped in a 3D forest of microscopic particles.

Using a new method for crunching vast sums in a model of particle interactions, a team of physicists in the US and France revealed conditions under which a wave of light can be brought to a standstill by defects in the right kind of material.

Known as Anderson localization, after US theoretical physicist Philip W. Anderson, electrons can become trapped (localized) in disordered materials with randomly distributed abnormalities. Its proposal in 1958 was a significant moment in contemporary condensed matter physics, applying across quantum as well as classical mechanics.

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Reliable analyst Ming-Chi Kuo is reporting that Apple is planning to adopt Wi-Fi 7 support on the iPhone as soon as next year. This could bring major improvements not only to speed and reliability, but also for the ability for different Wi-Fi 7 devices to interact with one another.

One of the biggest changes in Wi-Fi 7 is a dramatic increase in the maximum data throughput speeds. According to the Wi-Fi Alliance, Wi-Fi could offer peak data rates of more than 40Gbps, making it up to four times faster than Wi-Fi 6 And Wi-Fi 6E, and nearly six times faster than Wi-Fi 5.

In addition to those impressively fast speeds, Wi-Fi 7 will also introduce something called Multi-Link Operation technology. This will allow devices to simultaneously send and receive data over multiple radio bands. One of the biggest changes is an increase in the number of multi-user MIMO (multi-user, multiple input, multiple output) streams, doubling from eight to 16.

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Optical data communications lasers can transmit several tens of terabits per second, despite a huge amount of disruptive air turbulence. ETH Zurich scientists and their European partners demonstrated this capacity with lasers between the mountain peak, Jungfraujoch, and the city of Bern in Switzerland. This will soon eliminate the necessity of expensive deep-sea cables.

The backbone of the internet is formed by a dense network of fiber-optic cables, each of which transports up to more than 100 terabits of data per second (1 terabit = 1012 digital 1/0 signals) between the network nodes. The connections between continents take place via deep sea networks—which is an enormous expense: a single cable across the Atlantic requires an investment of hundreds of millions of dollars. TeleGeography, a specialized consulting firm, announced that there currently are 530 active undersea cables—and that number is on the rise.

Soon, however, this expense may drop substantially. Scientists at ETH Zurich, working together with partners from the , have demonstrated terabit optical data transmission through the air in a European Horizon 2020 project. In the future, this will enable much more cost‑effective and much faster backbone connections via near-earth satellite constellations. Their work is published in the journal Light: Science & Applications.

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Opera says its generative AI-infused browser is ready for public consumption. Opera One is now out of early access. It’s more broadly available on Windows, Mac and Linux. You can download it from the company’s website.

Opera features an integrated AI called Aria that you can access from the sidebar. You can use a keyboard shortcut (CTRL or Command and /) to start using Aria as well. The AI is also available in Opera’s Android browser starting today.

The AI stems from Opera’s partnership with ChatGPT creator OpenAI. Aria connects to GPT to help answer users’ queries. The AI incorporates live information from the web and it can generate text or code and answer support questions regarding Opera products. In addition, Opera One can generate contextual prompts for Aria when you right click or highlighting text in the browser. If you prefer to use ChatGPT or ChatSonic, you can access those from the Opera One sidebar too.

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Aleksandra Radenovic, head of the Laboratory of Nanoscale Biology in the School of Engineering, has worked for years to improve nanopore technology, which involves passing a molecule like DNA through a tiny pore in a membrane to measure an ionic current. Scientists can determine DNA’s sequence of nucleotides—which encodes genetic information—by analyzing how each one perturbs this current as it passes through. The research has been published in Nature Nanotechnology.

Currently, the passage of molecules through a and the timing of their analysis are influenced by random physical forces, and the rapid movement of molecules makes achieving high analytical accuracy challenging. Radenovic has previously addressed these issues with optical tweezers and viscous liquids. Now, a collaboration with Georg Fantner and his team in the Laboratory for Bio-and Nano-Instrumentation at EPFL has yielded the advancement she’s been looking for—with results that could go far beyond DNA.

“We have combined the sensitivity of nanopores with the precision of scanning ion conductance microscopy (SICM), allowing us to lock onto specific molecules and locations and control how fast they move. This exquisite control could help fill a big gap in the field,” Radenovic says. The researchers achieved this control using a repurposed state-of-the-art scanning ion conductance microscope, recently developed at the Lab for Bio-and Nano-Instrumentation.

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