Ceti AI acquires Big Energy Investments Inc. to enhance high-performance computing capabilities in North America

Vancouver, Canada, April 18, 2024, Chainwire

Chey Eye, a leader in distributed artificial intelligence infrastructure, is pleased to announce the acquisition of Big Energy Investments Inc., a Canadian company specializing in strategic investments in high-performance computing infrastructure. This acquisition is an important step in CeτiAI's strategy to advance the development and accessibility of AI technology.

Strategic acquisitions and enhancements

Following the acquisition, Big Energy Investments, Ltd. has an advanced high-performance computing (HPC) infrastructure that includes five HPC servers equipped with eight NVIDIA H100 Tensor Core GPUs and two NVIDIA Quantum-2 InfiniBand switches. We have reached a basic agreement to acquire it. These agreements are expected to be signed within the next week and underline our commitment to rapidly increasing our technological capabilities.

This strategic enhancement is critical to the initial deployment of the ceτi AI Infrastructure Network in North America, leveraging the ceτi AI Intelligent Computing Fabric to support decentralized AI networks, decentralized physical infrastructure networks (DePIN), and Manages and provides computing resources to a variety of other applications. .

Strategic development and pilot implementation

The new HPC infrastructure will support the first North American deployment of the ceτi AI Intelligent Computing Fabric, which manages the ceτi AI Infrastructure Network. The network is designed to provide essential computing resources to a variety of decentralized client networks and is a key component of ceτi AI's broader mission to democratize AI technology through decentralization. The pilot implementation will not only demonstrate the capabilities of the ceτi AI solution, but will also begin revenue generation and accumulation for the CETI token ecosystem.

Roadmap and future plans

Successful integration and demonstration of this infrastructure will set the stage for immediate expansion to data center-scale implementations, significantly scaling up ceτi AI's operational capabilities. The development of the CETI token ecosystem continues and its introduction is the next major milestone in the ceτi AI roadmap.

executive insights

“This acquisition is an important milestone in ceτi AI's growth trajectory and is consistent with our strategic objectives to strengthen our infrastructure and accelerate the development of decentralized AI technology. Big Energy Investments' resources and By combining our capabilities, we will be able to innovate and expand our reach across North America,” said Dennis Jarvis, CEO of ceτi AI.

Forward-looking statements

This press release contains forward-looking statements regarding expected future events and anticipated results that are subject to significant risks and uncertainties. These include, but are not limited to, final procurement and integration of HPC infrastructure, deployment and performance of the ceτi AI Intelligent Computing Fabric, and broader adoption and impact of the CETI token ecosystem. Actual results and results may differ materially from those expressed or anticipated in such forward-looking statements due to a variety of factors.

About ceτi AI

Chey Eye is at the forefront of revolutionizing artificial intelligence through decentralization. ceτi AI is committed to innovation and accessibility, developing a globally distributed, high-performance, scalable AI infrastructure designed to empower developers and networks around the world. ceτi AI aims to accelerate the advancement of AI technology by democratizing access to cutting-edge resources, making it more diverse and accessible to everyone. Our mission is not limited to infrastructure development. We are building the foundation for the future of AI, allowing it to grow in ways that benefit all of humanity without sacrificing freedom of choice and expression.

Users can learn more about our mission, technology, and the future we're building, along with the latest updates and community discussions, by visiting:

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Chey Eye
press@taoceti.ai

Source: the-blockchain.com

Signs of Potentially Weakening Dark Energy

Slice of the universe's largest 3D map showing the fundamental structure of matter

A collaboration between Leah Raman and DESI. Custom colormap package with cmastro

The largest 3D map of the universe ever created offers hints about the evolution of the universe and suggests we may be wrong about the behavior of dark energy, which makes up most of the universe. I am. This mysterious power may weaken over time.

“If it can be maintained, this is a very big deal,” he says Adam Rees Johns Hopkins University in Maryland discovered the first evidence of dark energy 25 years ago. That's because the standard model of cosmology, called the lambda CDM, suggests that the intensity of dark energy should not change over time.

Dark energy is thought to cause the accelerated expansion of the universe. If it is not static, it could also have major implications for our ideas about the universe's beginning, its size, and ultimate fate. Mr. Reese, who was not involved in the new work, said the impact was that “we… [our understanding of] “Gravity and Field”.

This strange finding comes from the Dark Energy Spectroscopy Instrument (DESI) in Arizona, where even DESI collaborators say data suggests dark energy may be weakening in recent times. I don't really know what to make of that fact. A DESI spokesperson said: “Whether this is interesting or not, this is all we have been talking about in this collaboration for months.” Kyle Dawson at the University of Utah.

DESI researchers investigated the strength of dark energy by measuring the large-scale structure and distribution of galaxies in the universe, revealing how the universe has expanded over time. The researchers then combined this information with three sets of data about supernovae. Supernovae act as so-called “standard candles” that determine the distance to cosmic objects thanks to their predictable brightness.

Surprisingly, each of the three supernova samples gave a different answer to the changing rate of expansion of the universe over time. All three suggest that the influence of dark energy may have declined in recent years, but the strength of these suggestions varies, so researchers wonder how to interpret the data. I don't really understand.

“Two of the supernova samples don't match each other, but they are very similar,” Dawson said. “We don't know which one is correct. The truth may lie somewhere in between, but the real difference seems to be in the method.” [the supernova researchers] We evaluated the data. ”

Model discrepancy is indicated by a coefficient called sigma. Sigma measures the likelihood that similar collisions will occur by chance when the models do not match each other. “About 3 sigma is the level at which we typically sit and pay attention and call it a 'sign' of something,” Reese says. Values ​​lower than that are usually not of particular interest to researchers. It would be too likely a simple coincidence.

The discrepancies between the lambda CDM and combined supernova and DESI measurements ranged from 2.5 sigma to 3.9 sigma. “Both opinions are true. There's enough tension and it's interesting. And there's not enough tension to say that something is definitely there,” says Dawson.

Dark energy makes up nearly 70 percent of the universe, so errors in our understanding of its properties can have far-reaching implications for physics. However, more precise measurements will be needed in the coming years to prove whether the error really exists.

“if [this is] “Certainly, this is the first real clue we've had about the nature of dark energy in 25 years,” says Rees.

topic:

Source: www.newscientist.com

Gigapixel Images of Bella Supernova Remnant Captured by Dark Energy Camera

Astronomers harness powerful energy dark energy camera The Victor M. Blanco 4-meter Telescope (DECam) at Cerro Tororo Inter-American Observatory, a program of NSF's NOIRLab, Huge 1.3 gigapixel image The Vela supernova remnant is the remains of a giant star that exploded in the constellation Vela about 11,000 years ago.

This DECam image shows the Vela supernova remnant, the remnant of a supernova explosion 800 light-years away in the southern constellation of Vela. Image credits: CTIO / NOIRLab / DOE / NSF / AURA / TA University of Alaska Anchorage Chancellor and NSF's NOIRLab / M. Zamani and D. de Martin, NSF's NOIRLab.

of Bella supernova remnantVela SNR for short, is one of the most well-studied supernova remnants in the sky and one of the closest supernova remnants to Earth.

Its progenitor star exploded 11,000 to 12,300 years ago south of the constellation Vore.

The association of this supernova remnant with the bella pulsar, made by Australian astronomers in 1968, provided direct observational evidence that supernovae form neutron stars.

“When this star exploded 11,000 years ago, its outer layer was violently stripped away and splattered around, creating a shock wave that can still be seen today,” the astronomers said in a statement.

“As the shock wave spreads into the surrounding region, hot, energetic gas flies away from the point of explosion, becomes compressed and interacts with the interstellar medium, producing the blue and yellow thread-like filaments seen in the image. .”

“Vela SNR is a gigantic structure, almost 100 light-years long and 20 times the diameter of a full moon in the night sky.”

“Although the star's final moments were dramatic, he did not completely disappear.”

“After the outer layers were shed, the star's core collapsed into a neutron star, an ultra-dense ball of protons and electrons that collided with each other to form neutrons.”

“The neutron star, named Bela pulsar, is now a supercondensed object containing the mass of a Sun-like star in a sphere just a few kilometers in diameter.”

“The Bela pulsar, located in the lower left region of this image, is a relatively faint star and indistinguishable from the thousands of objects next to it.”

Vela SNR's new image is the largest DECam image ever published, containing an astonishing 1.3 gigapixels.

“The striking reds, yellows, and blues in this image were achieved by using three DECam filters, each collecting a specific color of light,” the researchers said.

“Separate images were taken with each filter and stacked on top of each other to produce this high-resolution color image showing the intricate web-like filaments snaking throughout the expanding gas cloud.”

Source: www.sci.news

AI’s insatiable appetite for data is only rivaled by its relentless demand for water and energy.

One of the most harmful myths about digital technology is that it is somehow weightless or immaterial. Remember the early talk about “paperless” offices and “frictionless” transactions? And of course, our personal electronic devices Several Electricity is insignificant compared to a washing machine or dishwasher.

But even if you believe this comforting story, you might not survive when you come across Kate Crawford’s seminal book. Atlas of AI or impressive Structure of an AI system A graphic she created with Vladan Joler. And it definitely won’t survive a visit to the data center. One giant metal shed houses tens or even hundreds of thousands of servers, consuming large amounts of electricity and requiring large amounts of water for cooling systems.

On the energy side, consider Ireland, a small country with a huge number of data centers. According to a report by the Central Bureau of Statistics, these huts will be consumed in 2022 More electricity than every rural home in the country (18%), and as much as any urban dwelling in Ireland. And as far as water consumption is concerned, a 2021 Imperial College London study estimates: One medium-sized data center used the same amount of water as three average-sized hospitals. This serves as a useful reminder that while these industrial warehouses embody the metaphor of “cloud computing,” there’s nothing foggy or fluff about them. If you’re tempted to see it for yourself, forget it. Getting into Fort Knox should be easy..

There are currently between 9,000 and 11,000 such data centers around the world. Many of them are old-style server farms with thousands or millions of cheap PCs that store all the data our smartphone-driven world generates, including photos, documents, videos, and recordings. It’s starting to look a little outdated. In such casual abundance.

what i was reading

shabby philanthropist
Read Deborah Doan’s book sharp review for alliance Tim Schwab’s critical book magazine, bill gates problem.

final write
Veteran commentator Jeff Jarvis think about giving up “About old journalism and its legacy industry,” in a BuzzMachine blog post.

slim picking
In his blog No Mercy/No Malice, Scott Galloway suggests that AI and weight loss drugs have a lot in common.

Source: www.theguardian.com

US judge stops government from monitoring energy usage of cryptocurrency mining.

The U.S. government has halted an investigation into a cryptocurrency mining operation over its rising energy use following a lawsuit from an industry accused by environmental groups of fueling the climate crisis.

A federal judge in Texas granted an interim order blocking new requirements to verify cryptocurrency miners’ energy use, stating that the industry would suffer “irreparable harm” if forced to comply.

The U.S. Department of Energy launched an “emergency” initiative last month to examine the energy usage of mining operations, which use computational power to mine currencies like Bitcoin.

The growth of cryptocurrencies and mining activities has led to a surge in electricity usage, with data centers popping up and even reviving coal-fired power plants for mining operations.

The federal government requires more information on big miners’ electricity use, as mining facilities provided a significant portion of total U.S. electricity demand last year. Globally, cryptocurrency mining is responsible for a notable portion of energy consumption.

Campaigners warn that the increased electricity consumption from cryptocurrency mining exacerbates the climate crisis, with mining operations releasing significant amounts of carbon dioxide each year.

Cryptocurrency mining is straining power grids, with instances of Bitcoin companies receiving energy credits to reduce power usage during peak demand periods.

The industry has managed to avoid an investigation it deems burdensome, citing political motives from the government. The debate continues on the regulation of cryptocurrency mining in the U.S.

The Blockchain Council of Texas and other groups argue that the government’s actions are aimed at limiting or eliminating Bitcoin mining in the U.S., causing concerns for the industry and its employees.

Source: www.theguardian.com

The Surprising Reason Why Mental Exertion Can Drain Our Energy

The myth that we only use 10 percent of our brains has been completely debunked. Perhaps this idea persists because it is so tempting to believe that you can become a genius simply by learning how to tap into your dormant 90 percent. In reality, no part of your brain can keep up with demands, and your brain is always switched on, even when you're asleep or not thinking at all.

But that doesn't necessarily mean that your brain uses the same amount of energy while daydreaming as it does when you're concentrating. We've all experienced the feeling of being mentally exhausted after concentrating on a difficult problem. It certainly feels like a lot of work to think about it in detail, but is it really? The answer is more nuanced than you might think.

It is true that the brain is a starving organ. “It's the most energy-intensive part of your body,” he says. Nili Ravi At University College London. It makes up about 2% of your body weight, but consumes about 20% of your energy at rest.

Most of this energy is used to maintain varying levels of electrical charge across the neuron's membrane. This unbalanced state must be restored after the neuron fires the signal. “That requires a lot of fuel,” he says. Ewan McNay at the University at Albany in New York.

Interestingly, when it comes to energy use, the brain doesn't differentiate between tasks we traditionally think of as “difficult” and tasks that come more naturally. This was the first…

Source: www.newscientist.com

JET fusion reactor in the UK achieves record-breaking energy output

Inside the JET fusion reactor

eurofusion

A 40-year-old nuclear fusion reactor in the UK has set a world record for energy output in its final run before permanent shutdown, scientists have announced.

The Joint European Taurus (JET) in Oxfordshire began operations in 1983. During its operation, it briefly became the hottest point in the solar system, reaching 150 million degrees Celsius.

The reactor's previous record was in 2021 for a reaction that lasted five seconds and produced 59 megajoules of thermal energy. However, it surpassed this in its final test in late 2023, using just 0.2 milligrams of fuel to sustain the reaction for 5.2 seconds, reaching an output of 69 megajoules.

This corresponds to an output of 12.5 megawatts, enough to power 12,000 homes, Mikhail Maslov of the UK Atomic Energy Agency said at a press conference on February 8.

Today's nuclear power plants rely on nuclear fission reactions, in which atoms are shattered to release energy and small particles. Fusion works in reverse, pushing smaller particles together into larger atoms.

Nuclear fusion can produce more energy without any of the radioactive waste produced by nuclear fission, but there is still no practical way to use the process in power plants.

JET trains atoms of two stable isotopes of hydrogen, deuterium and tritium, together in a plasma to create helium, releasing a huge amount of energy at the same time. This is the same reaction that powers our sun. This is a type of fusion reactor known as a tokamak, which uses rings of electromagnets to contain plasma in a donut shape.

Scientists conducted the final experiment using deuterium and tritium fuel on JET in October last year, and other experiments continued until December. However, the machine is now permanently closed and will be decommissioned over the next 16 years.

Juan Matthews Researchers at the University of Manchester in the UK say many secrets will be revealed during JET's dismantling. For example, how the reactor lining deteriorated from contact with the plasma, and where in the machine the precious tritium, worth around £30,000 a gram, is embedded. You can recover. This will be important information for future research and commercial reactors.

“It's great to have a little bit of a bang,” Matthews said. “It has a noble history. Now that it has served its purpose, we plan to squeeze out more information during the decommissioning period as well. So it's not sad. It's something to be celebrated.”

France's larger, more modern replacement for JET, the International Thermonuclear Experimental Reactor (ITER), is nearing completion, with first experiments scheduled to begin in 2025.

ITER construction project deputy director Tim Luce told a news conference that ITER plans to expand its energy output to 500 megawatts and possibly 700 megawatts.

“These are what I normally call power plant sizes,” he said. “They are at the lowest level of cost required for a power generation facility. Moreover, to obtain high fusion power and gain the timescale needs to be extended to at least 300 seconds, but from an energy production point of view it is probably less than an hour. So what JET has done is exactly a scale model of what we need to do with the ITER project.”

Another reactor using the same design, the Korea Superconducting Tokamak Advanced Research (KSTAR) device, recently succeeded in sustaining a reaction for 30 seconds at temperatures above 100 million degrees Celsius.

Other approaches to creating practical fusion reactors are also being pursued around the world, such as the National Ignition Facility at Lawrence Livermore National Laboratory in California. It fired a very powerful laser into the fuel capsule, a process called inertial confinement fusion, and was able to release almost twice the energy that was put into it.

topic:

Source: www.newscientist.com

UK’s JET fusion reactor achieves highest energy output in the world

A 40-year-old nuclear fusion reactor in the UK has set a world record for energy output in its final run before permanent shutdown, scientists have announced.

The Joint European Taurus (JET) in Oxfordshire began operations in 1983. During its operation, it briefly became the hottest point in the solar system, reaching 150 million degrees Celsius.

The reactor's previous record was in 2021 for a reaction that lasted five seconds and produced 59 megajoules of thermal energy. However, it surpassed this in its final test in late 2023, using just 0.2 milligrams of fuel to sustain the reaction for 5.2 seconds, reaching an output of 69 megajoules.

Inside the JET fusion reactor

eurofusion

This corresponds to an output of 12.5 megawatts, enough to power 12,000 homes, Mikhail Maslov of the UK Atomic Energy Agency said at a press conference on February 8.

Today's nuclear power plants rely on nuclear fission reactions, in which atoms are shattered to release energy and small particles. Fusion works in reverse, pushing smaller particles together into larger atoms.

Nuclear fusion can produce more energy without any of the radioactive waste produced by nuclear fission, but there is still no practical way to use the process in power plants.

JET trains atoms of two stable isotopes of hydrogen, deuterium and tritium, together in a plasma to create helium, releasing a huge amount of energy at the same time. This is the same reaction that powers our sun. This is a type of fusion reactor known as a tokamak, which uses rings of electromagnets to contain plasma in a donut shape.

Scientists conducted the final experiment using deuterium and tritium fuel on JET in October last year, and other experiments continued until December. However, the machine is now permanently closed and will be decommissioned over the next 16 years.

Juan Matthews Researchers at the University of Manchester in the UK say many secrets will be revealed during JET's dismantling. For example, how the reactor lining deteriorated from contact with the plasma, and where in the machine the precious tritium, worth around £30,000 a gram, is embedded. You can recover. This will be important information for future research and commercial reactors.

“It's great to have a little bit of a bang,” Matthews said. “It has a noble history. Now that it has served its purpose, we plan to squeeze out more information during the decommissioning period as well. So it's not sad. It's something to be celebrated.”

France's larger, more modern replacement for JET, the International Thermonuclear Experimental Reactor (ITER), is nearing completion, with first experiments scheduled to begin in 2025.

ITER construction project deputy director Tim Luce told a news conference that ITER plans to expand its energy output to 500 megawatts and possibly 700 megawatts.

“These are what I normally call power plant sizes,” he said. “They are at the lowest level of cost required for a power generation facility. Moreover, to obtain high fusion power and gain the timescale needs to be extended to at least 300 seconds, but from an energy production point of view it is probably less than an hour. So what JET has done is exactly a scale model of what we need to do with the ITER project.”

Another reactor using the same design, the Korea Superconducting Tokamak Advanced Research (KSTAR) device, recently succeeded in sustaining a reaction for 30 seconds at temperatures above 100 million degrees Celsius.

Other approaches to creating practical fusion reactors are also being pursued around the world, such as the National Ignition Facility at Lawrence Livermore National Laboratory in California. It fired a very powerful laser into the fuel capsule, a process called inertial confinement fusion, and was able to release almost twice the energy that was put into it.

Source: www.newscientist.com

Nuclear fusion reactions produce nearly double the energy they consume

Nuclear fusion experiments at the US National Ignition Facility reach a significant milestone

philip saltonstall

Scientists confirmed that a 2022 fusion reaction reached a historic milestone by releasing more energy than it put in, and subsequent tests yielded even better results. Says. The findings, now published in a series of papers, offer encouragement that fusion reactors will one day produce clean, abundant energy.

Today's nuclear power plants rely on nuclear fission reactions, in which atoms are shattered to release energy and small particles. Fusion works in reverse, pushing smaller particles together into larger atoms. The same process powers our sun.

Nuclear fusion can produce more energy without any of the radioactive waste that comes with nuclear fission, but science has yet to find a way to contain and control the process, let alone extract energy from it. Researchers and engineers couldn't find it for decades.

Experiments to do this using laser-irradiated capsules of deuterium and tritium fuel – a process called inertial confinement fusion (ICF) – began in 2011 at California's Lawrence Livermore National Laboratory (LLNL) . Initially, the energy released was only a fraction of the energy. The laser energy input was gradually increased and the experiment finally crossed the important break-even milestone on December 5, 2022. That reaction generated his 1.5 times the laser energy needed to kickstart.

One paper claims that the institute's National Ignition Facility (NIF) has seen even higher ratios in subsequent commissioning, peaking at 1.9 times its energy input on September 4, 2023. .

Richard Towne LLNL said it believes the team's checks and double-checks since the 2022 results have proven it was “not a flash in the pan” and there is still room for improvement.

Town said yields are likely to improve with the hardware currently in place at NIF, but things could move further if the lasers can be upgraded, which would take years. “A sledgehammer always comes in handy,” he says. “If I could get a bigger hammer, I think I could aim for a gain of about 10.”

But Town points out that NIF was never built as a prototype reactor and is not optimized for high yields. His main job is to provide critical research to the US nuclear weapons program.

Part of this research involves exposing the bomb's electronics and payload to the neutron irradiation that occurs during the ICF reaction to see if they would function in the event of an all-out nuclear war. The risk of electronic equipment failure was highlighted during a 2021 test when NIF opened fire, knocking out all lights throughout the site, plunging researchers into darkness. “These lights were not hardened, but you can imagine military components having to withstand much higher doses,” Town says.

This mission means that some of the project's research remains classified. Until the 1990s, even the concept of ICF was secret, Town says.

The announcement that ICF would reach break-even in 2022 raised hopes that fusion power is on the horizon, and this will be further strengthened by news that further progress has been made. However, there are some caveats.

First, the energy output is far below what is needed for a commercial reactor, producing barely enough to heat a bath. What's worse is that this ratio is calculated using the power of the laser, so for him to produce 2.1 megajoules of energy, the laser consumes her 500 trillion watts. That's more power than the output of the entire U.S. national power grid. Therefore, these experiments apply even in a very narrow sense.

martin freer The researchers, from the University of Birmingham in the UK, say these results certainly do not indicate that a practical fusion reactor can now be built. “Science still has work to do,” he says. “We don't know the answers to all of these, and we don't need researchers anymore.”

Freer says that as scientific experiments advance, they pose engineering challenges to create better materials and processes, which in turn enables better experiments and further progress. “Nuclear fusion could happen,” he says. “But the challenges we face are quite steep from a scientific perspective.”

Aneeka Khan The professor at the University of Manchester, UK, agrees that recent advances in fusion research are positive, but stresses that it will be decades before commercial power plants are operational, and that only global cooperation and He stressed that it depends on a concerted effort to train more people. field. She cautions against interpreting advances in fusion research as a possible solution to dealing with dependence on energy from fossil fuels.

“Fusion is already too slow to address the climate crisis. We are already facing the devastation of climate change on a global scale,” says Khan. “In the short term, we need to leverage existing low carbon technologies such as nuclear fission and renewables, and in the long term, invest in fusion to become part of a diverse low carbon energy mix. must commit to tackling the climate crisis.”

topic:

  • nuclear energy/
  • nuclear fusion power generation

Source: www.newscientist.com

IEA warns that record growth in renewable energy in 2023 will still fall short

China played a big role in the growth of solar and wind power in 2023

Yuan Yuan Xie / Alamy Stock Photo

According to one study, 2023 will see a record expansion of renewable energy, with nearly 50% more solar, wind, and other clean energy sources built than in 2022. report From the International Energy Agency (IEA). But this unprecedented pace lags behind the pace needed to reach net-zero emissions and limit dangerous climate warming by mid-century.

“When you look at the numbers, it definitely has a ‘wow’ effect.” Fatih Birolsaid the IEA Director-General at a press conference today. “Renewable energy expansion exceeds 500 gigawatts in 2023.”

Under existing policies, the IEA predicts that renewable energy will overtake coal to account for the largest share of global electricity in 2025. The IEA predicts that by the end of 2025, renewable energy capacity will increase by 2.5 times. “It's very good news,” Birol said.

This is a significantly higher increase than projections made ahead of the COP28 climate change summit to be held in Dubai in December 2023. report A paper published last November by British energy think tank Ember found that the world is on track to double production capacity by the end of 2010.

but, dave jones At Ember said this difference is mainly due to the latest data on China's unusual development of solar and wind power, rather than policy changes or new project announcements in the past few months. The IEA report says China will have access to more solar energy in 2023 than the entire world saw in 2022.

“China is the most important driver of this impressive growth that we will see in 2023,” Birol said. He also pointed to record renewable energy capacity increases in the US, Europe, Brazil and India as a key driver of the surge.

Nevertheless, the IEA forecasts that the world still lags behind the goal of tripling renewable energy capacity by 2030, one of the key outcomes agreed at COP28. .

“We're not there yet, but we're not miles away from that goal,” Birol said, adding that officials are concerned about what the COP28 goals on clean energy and methane will do in the “real world.” It added that it plans to closely monitor the situation.

Closing the renewable energy gap will require different interventions in different regions of the world, the report says. In high-income countries, this will include improving electricity grids and speeding up the granting of permits for large backlogs of energy projects. Low-income countries need improved access to finance for clean energy projects.

“We are talking about transitioning away from fossil fuels, but there are still many economies in Africa that are in debt,” he says. Amos Wemanya Speaking at PowerShift Africa, a Kenyan energy think tank, he added that some of the continent's clean energy investments are going to rich countries.

Mr Jones said if the twin COP28 targets of tripling renewable energy and doubling energy efficiency were met by the end of 2010, global carbon dioxide emissions would be cut by more than a third and fossil fuels would be cut by more than a third. It says it could start to be replaced by fuel. “2024 will be the year renewable energy goes from being a nuisance to an existential threat to the fossil fuel industry,” he says.

topic:

Source: www.newscientist.com

The First Tunnel into a Magma Chamber Could Tap into Endless Energy Sources

Iceland is one of the most boring countries in the world. That’s a compliment, not an insult. The island nation is dotted with thousands of boreholes dug deep into the bedrock to extract geothermal energy. You’ll soon be joined by another team, but it’s never boring. “We are planning to drill into the magma chamber,” says Hjalti Pár Ingolsson from Reykjavík’s Geothermal Research Cluster (GEORG). “This is our first trip to the center of the Earth,” says his colleague Björn Sor Gudmundsson.

Well, not in the center. Some magma chambers (underground reservoirs of molten rock) lie just a few kilometers below the earth’s surface and are within reach of modern excavators. Sometimes magma leaks to the surface and erupts as lava. At the time this story went to press, that’s exactly what was beginning to have spectacular and devastating effects around the town of Grindavik in southern Iceland. The problem is that we usually don’t know where the magma chamber is. “No geophysical method has yet been proven to satisfactorily locate magma chambers,” he says. John Eichelberger At the University of Alaska Fairbanks.

But now Ingolfsson and his colleagues are in luck. They accidentally discover a magma chamber and are planning to do the unthinkable: to intentionally drill into it. This project is nothing short of making scientific history by providing the first direct opportunity to study the hidden liquid rock that Earth used to build its continents. On the way, it could also be…

Source: www.newscientist.com

Photoswitches: a revolutionary way to store solar energy

Groundbreaking research has identified a molecular photoswitch that can improve solar energy storage. Researchers used quantum computing to analyze large databases to find the best molecules for the technology, taking an important step in harnessing emissions-free solar energy. Credit: SciTechDaily.com

Optimization of molecular photoswitches for solar power generation.

Molecular photoswitches that can both convert and store energy could potentially make harvesting solar energy more efficient. The research team quantum computing A method of finding molecular structures that is particularly efficient for this purpose.As the team explained in the journal Angewante ChemieTheir procedure was based on a dataset of more than 400,000 molecules that were screened to find the best molecular structures for solar energy storage materials.

MOST project: new solar energy pathways

Currently, solar energy is used directly to generate electricity or indirectly through energy stored in thermal storage. A third route could involve first storing energy from the sun in a photosensitive material and then releasing it when needed. The EU-backed project MOST (‘Molecular Solar Thermal Energy Storage’) is researching molecules such as photoswitches that can absorb and store solar energy at room temperature, in order to make the use of completely emission-free solar energy a reality. Masu.

A research team led by Kurt V. Mikkelsen of the University of Copenhagen, Denmark, and Kasper Moss Poulsen of the Polytechnic University of Barcelona-Catalunya, Spain, took a closer look at the photoswitches that are ideal for this task. They studied molecules known as bicyclic dienes, which switch to a high-energy state when exposed to light. The most prominent example of this bicyclic diene system is known as norbornadiene quadricyclane, but a vast number of similar candidates exist. The researchers explain: “The resulting chemical space consists of approximately 466,000 bicyclic dienes that we screened for potential applicability to MOST technology.”

Innovative screening methods and promising discoveries

Screening a database of this size is typically done as follows: machine learning, But this would require large amounts of training data based on real-world experiments, which the team didn’t have. Screening and evaluation of database molecules using previously developed algorithms and the new evaluation score “Eta” yielded clear results. All six of his top-scoring molecules differed from the original norbornadienequadricyclane system in important structural respects. The researchers concluded that this structural change, an enlargement of the molecular bridge between the two carbon rings of the bicyclic moiety, allowed the new molecule to store more energy than the original norbornadiene.

The researchers’ work demonstrates the potential for optimizing solar energy storage molecules. However, new molecules must first be synthesized and tested under real conditions. “Even if systems can be prepared synthetically, there is no guarantee that they will be soluble in the relevant solvents and will actually photoswitch in high yields, as we envisioned with Eta, or “There is no guarantee that there will be any optical switching at all,” the authors caution.

Impact and prospects

Nevertheless, the team developed a new large-scale training data set for machine learning algorithms, shortening difficult pre-synthetic research steps for chemists working on such systems in the future. The authors envision that this much larger reservoir of bicyclic dienes could be exploited to study photoswitches for a variety of applications, making it easier to tailor molecules to specific requirements. doing.

References: “Bicycles for Molecular Solar Energy Storage Candidates” by Andreas Arbus Hillers Bentsen, Jacob Linge Erholm, Oskar Berlin Ober, Helen Herzel, Kaspar Moss Poulsen, and Kurt V. Mikkelsen. Exploring the chemical space of formula dienes”, July 25, 2023, Angewante Chemie International Edition.
DOI: 10.1002/anie.202309543

Source: scitechdaily.com

Enhanced Energy Storage Capacity of Hybrid Supercapacitor Electrodes

A breakthrough in hybrid supercapacitors was achieved by increasing the active material in the electrodes by a new method involving β-Ni(OH)2 and NH4F. This innovation leads to more efficient energy storage and opens new possibilities for advanced energy systems. Credit: SciTechDaily.com

New research enhances hybrid supercapacitors by creating more efficient electrodes, marking a major advance in energy storage technology.

Like batteries, supercapacitors are a type of energy storage device. However, whereas batteries store energy electrochemically, supercapacitors store energy electrostatically by storing charge on the electrode surface.

Hybrid supercapacitors (HSCs) combine the advantages of both systems by incorporating battery-type electrodes and capacitor-type electrodes. Despite synthetic techniques that allow the active components of HSC electrodes to be grown directly on conductive substrates without the addition of binders (“self-supporting” electrodes), the proportion of active material in these electrodes remains subject to commercial requirements. remains too low.

Now, researchers have discovered a clever way to increase activity ratios and achieve dramatic improvements in key measures.

Schematic diagram of the device. Credit: Vinod Panwar and Pankaj Singh Chauhan

A breakthrough in supercapacitor electrode efficiency

“Hybrid supercapacitors integrate the advantages of high energy and power density, long cycle life, and safety, and are emerging as a promising frontier in electrochemical energy storage,” said the study’s lead author, a Chinese said Wei Guo, a scientist at Northwestern University of Science and Technology.

“In our paper, we propose a new mechanism to create a versatile two-dimensional superstructure family that overcomes the low active mass ratio of conventional free-standing electrodes.”

New methodology and findings

Here, the researchers studied β-Ni(OH)2, a type of nickel hydroxide. Addition of NH4F into the reaction solution replaces one hydroxide ion with a fluoride ion. The resulting Ni-F-OH plates were grown to a thickness of 700 nm and had a high mass loading (active mass per cm2) 29.8 mg cm-2– Up to 72% of electrode mass.

Advanced Light Source (ALS) Many theoretical and An experimental analysis was performed. It is used to understand the mechanisms underlying the new morphology.

As a result, adding F gives us Ions tune the surface energy of the plates (a key factor in nanocrystal growth), while NH4+ Ions consume excess local OHsuppressing undesired β-Ni(OH)2 reformation. Additionally, based on the same methodology, researchers can produce other bimetallic superstructures and their derivatives, emerging a versatile new family of metal-based hydroxides for new energy storage systems to meet future demands. showed signs of.

Reference: “New layered hydroxide plates of record thickness to enhance high mass-load energy storage” Wei Guo, Chaochao Dun, Matthew A. Marcus, Victor Venturi, Zack Gainsforth, Feipen Yang, Xuefei Feng, Venkatasubramanian Viswanathan, Jeffrey J. Urban, Chang Yu, Qiuyu Zhang, Jinghua Guo, Jieshan Qiu, February 18, 2023. advanced materials.
DOI: 10.1002/adma.202211603

Source: scitechdaily.com

Akron Energy secures $110 million investment to expand Bitcoin mining operations and launch AI cloud services in Norway

Akron Energy data center infrastructure company has closed a $110 million private funding round to expand its business, CEO Josh Payne exclusively tells TechCrunch.

The round was led by Bluesky Capital Management with participation from Kestrel 0x1, Nural Capital, and Florence Capital.

The company was founded in 2021 and started with a 5-megawatt site in Australia. Since then, its output has grown to over 130 MW, and it has expanded to other countries and regions such as the United States and Europe.

“These sites are attractive to both Bitcoin miners and AI.” [or] It’s a machine learning client that requires very high-powered computing,” Payne said. By the way, statistics show that 1 megawatt can power 400 to 900 homes per year. Nuclear Regulatory Commission.

Approximately $80 million will be used to acquire an additional 200 megawatts of capacity across new data centers in Ohio, North Carolina, and Texas as part of the company’s plan to increase its total megawatt capacity by 130% by mid-2024. be exposed. This is in addition to an existing 100-megawatt facility in Ohio that Akron purchased in June, Payne noted.

“The United States is an attractive market for us in many ways, primarily due to huge domestic customer demand, a mature and robust energy industry with multiple flexible deregulated markets, and a strong political and・Regulatory stability and attractiveness to institutional investors,” Payne said. “The United States has a wealth of underutilized and stranded generation assets that are connected to some of the lowest-cost power sources in the world, many of which are renewable.”

Payne said the majority of the company’s U.S. data center portfolio is made up of institutional-grade Bitcoin mining companies. “We are essentially landlords who own the underlying infrastructure assets.”

Akron’s business model is focused on strategically acquiring distressed data center assets around the world. “The current and future demand for data center capacity of all types seen around the world, especially in the United States, is unprecedented and huge. We have energy-intensive platforms that require significant amounts of electrical infrastructure.”

The remaining $30 million will be used to develop an artificial intelligence cloud services project at Akron’s data center in Norway to help serve the generative AI and large-scale language model training markets. “Over the past year, we have seen a significant acceleration in market demand for generative AI and large-scale learning model applications,” he said.

However, there is a lack of specialized physical infrastructure to power computers and support most of these products. Akron aims to fill that gap by providing the underlying infrastructure layer that the AI ​​sector relies on.

Over the past year, with spot ETF approval looming, on top of Bitcoin’s potential growth and adoption in the mainstream institutional market, there has been a “meteorous rise in AI applications,” such as Akron’s Specialized data centers are “poised to continue to grow exponentially,” Payne said.

Source: techcrunch.com

Unknown source of ultra-high energy extraterrestrial particle detected by telescope array

An artist’s illustration of an extremely high-energy cosmic ray, named the “Amaterasu particle,” observed by the surface detector array of the Telescope Array experiment.Credit: Osaka Metropolitan University/L-INSIGHT, Kyoto University/Ryuunosuke Takeshige

A groundbreaking detection of extremely high-energy cosmic rays by a telescope array experiment points to a void in the universe and casts doubt on current theories about the origin and high-energy physics of cosmic rays. It raises questions about its source.

Discovery of an exceptional extraterrestrial particle

Researchers involved in the telescope array experiment announced that they had detected cosmic rays with unusual energy. This particle originates outside our galaxy and has an incredible energy level of more than 240 exaelectronvolts (EeV). Despite this remarkable discovery, its exact source remains elusive, as its direction of arrival does not point to any known celestial body.

The mystery of ultra-high energy cosmic rays

Cosmic rays are subatomic charged particles that come from space, and ultra-high energy cosmic rays (UHECRs) are a rare and extremely powerful type. These UHECRs have energies in excess of 1 EeV, which is about a million times the energy reached by man-made particle accelerators. These are thought to originate from the most energetic phenomena in the universe, such as black holes, gamma-ray bursts, and active galactic nuclei. However, its exact physics and acceleration mechanisms are still not fully understood. These high-energy cosmic rays occur infrequently, estimated at less than one particle per square kilometer per century, making their detection a rare event and requiring instruments with large collection areas. .

An artist’s illustration of ultra-high energy cosmic ray astronomy, which elucidates highly energetic phenomena as opposed to weak cosmic rays that are affected by electromagnetic fields.Credit: Osaka Metropolitan University/Kyoto University/Ryuunosuke Takeshige

A unique discovery of telescope arrays

The Telescope Array (TA) experiment, a large-scale surface detector array in Utah with an effective detection area of ​​700 square kilometers, successfully detected UHECR on May 27, 2021 at a breakthrough energy of approximately 244 EeV.

Given the very high energy of this particle, it should experience only a relatively small deflection by the foreground magnetic field, and therefore its direction of arrival should be expected to be more closely correlated with its source. Researchers point out that there is. However, our results show that the direction of arrival does not indicate an obvious source galaxy or other known objects that could be potential sources of UHECRs.

Instead, its direction of arrival points to a cavity in the large-scale structure of the universe, a region where galaxies are almost absent. Scientists believe this indicates a much larger magnetic deflection than predicted by galactic magnetic field models, an unidentified source in the local extragalactic neighborhood, or an incomplete understanding of the high-energy particle physics involved. This suggests that there is a possibility that

For more information on this discovery, see:

Reference: “Extremely high-energy cosmic rays observed by surface detector arrays”*†, RU Abbasi, MG Allen, R. Arimura, JW Belz, DR Bergman, SA Blake, BK Shin, IJ Buckland, BG Cheon, Tetsuya Fujii, Kazuya Fujisue, Kazuya Fujita, Masaki Fukushima, GD Furlich, ZR Gerber, N. Globus, Kazuto Hibino, Tatsuya Higuchi, Kazuya Honda, Daisho Ikeda, Hiroshi Ito, Akira Iwasaki, S. Jeong, HM Jeong, CH Jui, K. Kadota, F. Kakimoto, OE Kalashev, K. Kasahara, K. Kawata, I. Kharuk, E. Kido, SW Kim, HB Kim, JH Kim, JH Kim, I. Komae, Y. Kubota, MY Kuznetsov, KH Lee, BK Rubsandrjiev, JP Lundquist, JN Matthews, S. Nagataki, T. nakamara, A. Nakazawa, T. Nonaka, S. Ogio, M. Ono, H. Oshima, IH Park. , M. Potts, S. Pushilkov, JR Remington, DC Rodriguez, C. Lott, GI Rubtsov, D. Liu, H. Sagawa, N. Sakaki, T. Sako, N. Sakurai, H. Shin, JD Smith, P Sokolsky, BT Stokes, TS Stroman, K. Takahashi, M. Takeda, A. Takeda, Y. Tameda, S. Thomas, GB Thomson, PG Tyniakov, I. Tkachev, T. Tomita, SV Troitsky, Y. Tsunesada, S. Udo, FR Urban, T. Wong, K. Yamazaki, Y. Yuma, YV Zeser, Z. Zunder, November 23, 2023. science.
DOI: 10.1126/science.abo5095

Source: scitechdaily.com

Preparing Staff for the Shift to Clean Energy

clean innovation Technology and renewable energy are moving quickly, maybe a little too fast.

While there is no shortage of clean technology solutions available in today’s market (and we are developing them for the future), a new problem is emerging: a lack of talent to install and maintain the technology.

According to one study, the clean technology industry is expected to create 8 million jobs by the end of 2030. recent reports By the International Energy Agency. These numbers are clearly based on current policies, and the report’s authors expect these numbers to rise as more resources are directed to the clean energy transition. But just because more jobs are created doesn’t mean there are enough trained people to fill them.

Berlin-based Montamo wants to solve this problem. The startup hires and trains people to install and maintain sustainable heat pumps. We train people new to the industry, provide upskilling training to those with some experience, and have our employees install and maintain other companies’ equipment. As the company grows, it hopes to expand into other areas such as solar power generation.

Co-founder Alexander Boehm told TechCrunch+. Boehm said the company wants to be intentional about hiring and training migrant workers because it is difficult for immigrants to get good jobs in Germany, regardless of their skills or background. This is something Boehm witnessed firsthand when he worked as operations director for fast grocery delivery startup Gorillaz, and he doesn’t want their skills to go to waste.

Source: techcrunch.com

Scientists are puzzled by the detection of ultra-high energy particles plummeting towards Earth, according to Science and Technology News.

Astronomers have detected a rare and extremely energetic particle falling to Earth.

Scientists say the ray, named after the Japanese sun goddess Amaterasu, is one of the most energetic cosmic rays ever detected.

The Amaterasu particle has an energy of more than 240 exaelectron volts (EeV), making it the second particle in recorded history, after another ultra-high-energy cosmic ray, the Oh My God particle (320 EeV), detected in 1991.

The origins of the particles are unknown, but experts believe that only the most powerful astronomical phenomena, larger than an exploding star, can produce them.

Toshihiro Fujii, associate professor at Osaka Metropolitan University, Japansaid that when he first discovered this particle, he thought, “There must have been a mistake.”

“We’ve seen energy levels unprecedented in the last 30 years,” he said.

read more:
Images from the James Webb Telescope capture the center of the Milky Way
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Telescope captures first full-color image of the universe

The particle seems to come out of nowhere, further deepening the mystery for scientists.

John Matthews, a research professor in the University of Utah’s Department of Physics and Astronomy, explains that there was nothing in the area high-energy enough to cause this phenomenon.

It appeared to emerge from the Local Void, the empty space adjacent to the Milky Way.

“We should be able to point to where in the sky they came from,” Professor Matthews says.

“But in the case of the Oh My God particle and this new particle, even if we trace its trajectory back to its source, there is nothing high enough energy to produce it.

“That’s the mystery – what the hell is going on?”

Typically, when ultra-high-energy cosmic rays hit Earth’s atmosphere, they create a cascade of secondary particles and electromagnetic radiation known as a massive air shower.

Some charged particles in air showers travel faster than the speed of light and produce a type of electromagnetic radiation that can be detected with special equipment.

One of those instruments is the Telescope Array Observatory in Utah, which discovered the Amaterasu particle.

image:
Telescope Array Surface Detector in Utah.Photo: Associated Press

It is now hoped that this particle will pave the way for further research that will help uncover ultrahigh-energy cosmic rays and their origins.

Experts suggest this may indicate a much larger magnetic deflection than predicted, an unidentified source within the local void, or an incomplete understanding of high-energy particle physics.

Another Utah professor, John Beltz, said he was “throwing out crazy ideas” to try to explain the mystery.

“These events appear to be coming from completely different places in the sky. There is no one mysterious source,” he said. “It could be a flaw in the fabric of space-time, causing cosmic strings to collide.”

However, he added, “There is no conventional explanation.”

Source: news.sky.com