We are now one step closer to quantum computers that utilize diamond wafers.

New diamond wafers made in Japan can store 1 billion Blu-Ray discs of data

High-purity diamond wafer with a diameter of 2 inches.

The Japanese company <a href="https://www.ad-na.com/en/" rel="noopener noreferrer nofollow" target="_blank">Adamant Namiki Precision Jewel Co.</a> and researchers from <a href="https://www.saga-u.ac.jp/" rel="noopener noreferrer nofollow" target="_blank">Saga University</a> in Kyushu, Japan, have developed a new method to mass-produce two inch (5 cm) wafers made of diamond. 
While using diamonds is one of the most promising materials for <a href="https://interestingengineering.com/scientists-in-japan-build-harder-diamond-using-new-method" rel="dofollow">quantum computing systems</a>, too much nitrogen in a diamond disrupts its quantum storage capabilities.
The novel ultra-high-purity diamond contains no more than three parts per billion of nitrogen atoms, as required for quantum applications, such as quantum computers, quantum memory, and quantum sensing devices. 
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The diamond wafers, called Kenzan Diamond, could be used for quantum memory as the ultra-high purity of the diamond allows it to store a whopping 25 exabytes, the equivalent of one billion Blu-Ray discs, of data. 
Until now, <a href="https://interestingengineering.com/crystal-58-harder-than-diamond" rel="dofollow">usable diamond crystals</a> were only about four millimeter square. It is expected that this new technology will lead to the realization of quantum computers in the future. 
Diamond wafers are manufactured by growing the crystals on a substrate material, usually a flat surface. In diamond crystal growth technology, nitrogen gas has to be used to obtain a high growth rate, so nitrogen impurities with a concentration of several ppm are mixed into the diamond crystal and cannot be used in a quantum computer.
The main problem with this method is that the <a href="https://interestingengineering.com/scientists-in-japan-build-harder-diamond-using-new-method" rel="dofollow">diamond can crack under the strain</a>, degrading its quality. In the new method, the team uses a substrate surface that is shaped like steps, which spreads the strain horizontally and prevents cracking. This newly used surface allows them to make larger diamond wafers with higher purity.
The research will be presented at the International Conference on Compound Semiconductor Manufacturing Technology in May.
Adamant Namiki plans to commercialize Kenzen Diamonds in 2023, while working on doubling the size of the wafers.

The US Navy unveils a bold plan to convert oil rigs into mobile missile defense and resupply bases in the Pacific.

From oil rig to ocean fortress: US Navy to repurpose oil rigs for mobile defense

Deepsea Delta semi-submersible drilling rig in the North Sea 

The US Navy is charting a bold course with its latest initiative, the Mobile Defense/Depot Platform (MODEP) concept. Unveiled at the recent Sea Air Space 2024 expo, this project proposes a novel solution to address evolving security challenges in the Pacific: repurposing surplus oil rigs into mobile <a href="https://interestingengineering.com/military/israel-rampage-missile-against-iran" target="_blank" rel="dofollow">missile defense</a> and resupply bases.



<h3 class="wp-block-heading" id="h-the-modep-concept">The MODEP concept</h3>



Developed by Gibbs &amp; Cox, a Leidos company, the MODEP concept envisions transforming existing oil rigs into large, self-sufficient island bases. These mobile platforms would be strategically positioned at sea and operate independently for extended periods of up to 12 months.



The converted rigs boast impressive firepower potential. They can be equipped with either 512 vertical launch system (VLS) cells or 100 large missile launchers, a significant leap compared to the capacity of an <a href="https://interestingengineering.com/military/us-navy-certifies-virtualized-aegis-combat-system-on-its-first-destroyer" target="_blank" rel="dofollow">Arleigh Burke-class</a> destroyer (approximately five times greater). This enhanced capability translates to a more robust US air defense posture in the Pacific.



But the MODEP concept extends beyond pure defense. The platforms can also serve as Afloat Forward Staging Bases, providing logistical support for US Navy surface combatants and nuclear submarines. This dual functionality offers a strategic advantage, enhancing offensive and defensive capabilities. 



<figure class="wp-block-embed is-type-video is-provider-youtube wp-block-embed-youtube wp-embed-aspect-16-9 wp-has-aspect-ratio"><div class="wp-block-embed__wrapper">
<iframe loading="lazy" title="Mobile Defense/Depot Platform (MODEP) Concept at Sea Air Space 2024" width="500" height="281" src="https://www.youtube.com/embed/hvXU7Ow9OwY?feature=oembed" frameborder="0" allow="accelerometer; autoplay; clipboard-write; encrypted-media; gyroscope; picture-in-picture; web-share" referrerpolicy="strict-origin-when-cross-origin" allowfullscreen></iframe>
</div></figure>



<h3 class="wp-block-heading">Strategic advantages and cost-effectiveness</h3>



The US Navy sees these mobile platforms as a game-changer. Heruningtyas Desi Purnamasari, a Navy official, emphasizes the strategic importance of the MODEP concept. He highlights the potential for &#8220;a substantial reduction in risks and costs associated with land-based defense systems.&#8221;



Another key selling point is the project&#8217;s cost-effectiveness. Converting existing oil rigs is estimated to cost a mere 10% of the price tag associated with building a brand-new <a href="https://interestingengineering.com/innovation/aerojets-zeus-2-success-boosts-hypersonic-and-ballistic-missile-systems" target="_blank" rel="dofollow">Ballistic Missile Defense</a> (BMD) system. This significant cost savings makes the MODEP concept an attractive proposition in an era of tightening defense budgets.



<h3 class="wp-block-heading">Feasibility and potential challenges</h3>



Despite its promise, the MODEP concept has its critics. Experts have raised concerns about such large-scale floating bases&#8217; feasibility and potential drawbacks.



A 2018 Jose Delgado and Eviya Vitola study focused on the political and security challenges associated with semi-permanent offshore military installations. Their analysis identified potential vulnerabilities to missile attacks, high operational costs, and the relative ineffectiveness of these bases compared to conventional defense strategies.



However, more recent research by Sam Tangredi of the Foreign Policy Research Institute presents a counter-argument. Tangredi emphasizes the strategic benefits of sea bases, including improved joint command capabilities and rapid strike potential. He acknowledges the evolving nature of anti-access/area-denial (A2/AD) threats but questions whether air and missile defense advancements can adequately mitigate the risks associated with sea bases.



Ultimately, whether the MODEP concept represents a viable solution for the US Navy remains open for debate. While the project can potentially revolutionize naval defense strategies, its long-term effectiveness hinges on overcoming logistical and security challenges.



<h3 class="wp-block-heading">A shift in military strategy</h3>



The MODEP concept reflects a broader shift in US military strategy. As the geopolitical landscape evolves and technological advancements reshape warfare, the Navy is actively seeking to bridge the gap between traditional land-based defense systems and the vast capabilities offered by the open seas. The potential success of the MODEP project could pave the way for a new era of maritime-centric defense strategies.



<a rel="nofollow" href="Naval News">Source: Naval News</a>

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The quadruped robot dog is armed with the company&#8217;s ARC Flamethrower and is now available for $9,420.

‘World’s 1st’ flamethrower robot dog gets remote control and LiDAR

Screenshot: Flamethrower-wielding Thermonator robot dog can blaze up to 30 feet. 

A flame-throwing robot dog that can shoot blazes up to 30 feet (9 meters) is up for sale in the United States.



Throwflame, the manufacturer, claims the robot dog is the first of its kind and has a battery that can last for an hour.



The quadruped robot dog is armed with the company&#8217;s ARC Flamethrower and is available for $9,420.



<h3 class="wp-block-heading" id="h-thermonator-operations-and-control">Thermonator: Operations and control</h3>



<figure class="wp-block-image size-large"><img loading="lazy" decoding="async" width="1920" height="1080" src="https://cms.interestingengineering.com/wp-content/uploads/2024/04/flth-ezgif.com-resize.png?w=1920" alt="The Flamethrower Robot Dog." class="wp-image-60702" srcset="https://cms.interestingengineering.com/wp-content/uploads/2024/04/flth-ezgif.com-resize.png 1920w, https://cms.interestingengineering.com/wp-content/uploads/2024/04/flth-ezgif.com-resize.png?resize=300,169 300w, https://cms.interestingengineering.com/wp-content/uploads/2024/04/flth-ezgif.com-resize.png?resize=768,432 768w, https://cms.interestingengineering.com/wp-content/uploads/2024/04/flth-ezgif.com-resize.png?resize=1536,864 1536w" sizes="(max-width: 1920px) 100vw, 1920px" /><figcaption class="wp-element-caption">The Flamethrower Robot Dog.</figcaption></figure>



The quadruped robot dog is now operated by a first-person view (FPV) controller, a concept that is increasingly gaining traction with the rise of drones.



A laser mounted on the flamethrower provides the aim to the flames, which have a range of 30 feet.



Another interesting feature of the robot dog is its use of Light Detection and Ranging (commonly known as LiDAR) to guide it.



LiDAR <a href="https://interestingengineering.com/science/what-is-lidar-technology-and-what-are-its-main-applications" target="_blank" rel="dofollow">utilizes</a> pulsed lasers to accurately and constantly measure distances to a given target or area. LiDAR sensors are light-based measurement and mapping tools incredibly useful in various sectors. 



Per the company&#8217;s claims, it can also avoid obstacles and operate in remote areas.



The ARC Flamethrower, as per the description, is a compact all-electric flamethrower. &#8220;Ultra-modular and adaptable, the ARC can be configured in countless ways,&#8221; the company states.



The robot dog – also known as Thermonator – uses the ARC Flamethrower, giving it instant ARC ignition. It also has an extended battery life and a versatile mounting system, which gives the robot quadruped enhanced flexibility in operations.



<figure class="wp-block-embed is-type-video is-provider-youtube wp-block-embed-youtube wp-embed-aspect-16-9 wp-has-aspect-ratio"><div class="wp-block-embed__wrapper">
<iframe loading="lazy" title="The Robot Dog With A Flamethrower | Thermonator" width="500" height="281" src="https://www.youtube.com/embed/rj9JSkSpRlM?feature=oembed" frameborder="0" allow="accelerometer; autoplay; clipboard-write; encrypted-media; gyroscope; picture-in-picture; web-share" referrerpolicy="strict-origin-when-cross-origin" allowfullscreen></iframe>
</div></figure>



<h3 class="wp-block-heading" id="h-thermonator-s-agricultural-commercial-amp-military-use">Thermonator&#8217;s agricultural, commercial &amp; military use</h3>



Throwflame says all its products are designed for personal and commercial use, such as ground clearing or controlled agricultural burns, ice and snow melting, forest fire containment/ prevention, and film production.



In addition to the quadruped robot dog, the company <a href="https://throwflame.com/products/thermonator-robodog/" target="_blank" rel="noopener noreferrer nofollow" target="_blank">offers</a> hand-held flamethrowers, flamethrower drone attachments, and other products.



However, with the growing use of UAVs and robot vehicles in military operations, the armed forces could soon adopt them as well.



Various US armed forces have recently conducted&nbsp;<a href="https://interestingengineering.com/military/us-forces-drill-with-ghost-drones-robot-dogs-to-sync-battle-signals" rel="dofollow">training exercises</a>&nbsp;using drones, other robot dogs, and troops. Designed to make military units &#8220;more lethal and efficient,&#8221; the exercise was a useful testbed for future human and drone operations.



The exercise, called Project Convergence Capstone 4 (PC-C4), also included representatives from nations like the United Kingdom and Japan.



The training exercise also involved a mid-sized all-weather ground drone, the <a href="https://interestingengineering.com/innovation/next-generation-rifle-robot-dog" target="_blank" rel="dofollow">&#8220;robot dog</a>.&#8221;



<h2 class="wp-block-heading" id="h-thermonator-the-war-dog">Thermonator: The war dog? </h2>



This highly durable, agile ground drone can withstand various unstructured urban and natural environments. It is designed for defense, homeland security, and enterprise applications.



The promising results signal a possible integration of advanced tech into army units in the future.



The ongoing war between Russia and Ukraine has led to an increased usage of drones. Technology is challenging traditional warfare methods, and in the future, there will only be an upward rise in the number of drones deployed by armed forces across the globe.



Therefore, in the future, the Thermonator could be one of the top contenders among ground drones for possible military usage.

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A single-story bungalow could take a few months to build, but this printer can complete the project in less than four days.

World’s largest 3D printer can build a small house in 80 hours

Factory of the Future 1.0 (FoF 1.0) 3D printer

The University of Maine has smashed its own world record by creating the largest polymer 3D printer, paving the way for the future of sustainable manufacturing.



In 2019, they unleashed the first record-breaking 3D printer that constructed a 600-square-foot house made of recyclable materials. 



Built to meet a demand for more affordable housing, the state of Maine needs another 80,000 homes over the next six years with a shortage of manpower to make it happen.



The bigger and better Factory of the Future 1.0 (FoF 1.0) 3D printer is here to help its predecessor reach this goal of providing more for less.



<h3 class="wp-block-heading" id="h-the-fof-1-0-3d-printer-will-build-affordable-housing">The FoF 1.0 3D printer will build affordable housing</h3>



The university, with a longstanding relationship with the US government, wanted to demonstrate that a 3D printer could print a home with a lower carbon footprint &#8211; as the construction industry produces about 37% of greenhouse gas emissions, according to the United Nations Environment Program.



The FoF 1.0 prints four times faster, which means that it can print a bio home in about 80 hours. A single-story bungalow, for example, could take a few months to build, but this printer can complete the project in less than four days.



The goal wasn’t to build a cheap house, but rather to build one that people wanted to live in, said Dr Habib Dagher, the Director of the Advanced Structures and Composites Center at the University of Maine.



Present for the official unveiling of the FoF 1.0 were representatives from the US Department of Defense, Energy, the Maine State Housing Authority, as well as other stakeholders who plan to put this Factory of the Future 1.0 3D printer to good use.



<figure class="wp-block-image size-full"><img loading="lazy" decoding="async" width="1920" height="1080" src="https://cms.interestingengineering.com/wp-content/uploads/2024/04/fof-1340_inline-2.jpeg" alt="" class="wp-image-60767" srcset="https://cms.interestingengineering.com/wp-content/uploads/2024/04/fof-1340_inline-2.jpeg 1920w, https://cms.interestingengineering.com/wp-content/uploads/2024/04/fof-1340_inline-2.jpeg?resize=300,169 300w, https://cms.interestingengineering.com/wp-content/uploads/2024/04/fof-1340_inline-2.jpeg?resize=768,432 768w, https://cms.interestingengineering.com/wp-content/uploads/2024/04/fof-1340_inline-2.jpeg?resize=1536,864 1536w" sizes="(max-width: 1920px) 100vw, 1920px" /><figcaption class="wp-element-caption"><a href="https://umaine.edu/news/blog/2024/04/23/umaines-new-3d-printer-smashes-former-guinness-world-record-to-advance-the-next-generation-of-advanced-manufacturing/" target="_blank" rel="noopener noreferrer nofollow" target="_blank">University of Maine</a></figcaption></figure>



<h3 class="wp-block-heading" id="h-the-fof-1-0-the-future-of-manufacturing-and-defense">The FoF 1.0: The future of manufacturing and defense</h3>



The thermoplastic polymer printer can print objects as large as 96 feet long by 32 feet wide by 18 feet high — consuming 500 pounds of material per hour. 



Its applications range from industries to national security — meaning, if they need to build ships fast, they have the technology to do so. 



Though, typically, it takes years to build military ships, in WWII, the US manufactured the Liberty ships in 42 days. These large-scale 3D printers could feasibly meet that speed and maybe surpass it if needed. 



The applications of the 3D printer, however, are far-reaching.



“UMaine and the Advanced Structures and Composites Center possess the innovation, capacity, and workforce to support the future needs of the Department of Defense in advanced manufacturing,” said US Sen. Susan Collins. “This is a great day for our University, our State, and our Nation.”



Because the FoF 1.0 is so much more than a printer. It can switch functionalities between “additive manufacturing, subtractive manufacturing, continuous tap layup, and <a href="https://interestingengineering.com/innovation/35-gram-hopcopter-revolutionizes-robotics-with-its-hops-and-flight" target="_blank" rel="dofollow">robotic arm operations</a>.” 



It’s both a computer and a manufacturer that the Office of the Secretary of Defense and US Army Corps of Engineers helped to design and build.



The FoF 1.0 stands to revolutionize a variety of industries. That includes affordable housing, public works such as bridge construction, and ocean and wind energy. And it’s all recyclable.



“You can basically deconstruct it, grind it up if you wish, the 3D printed parts, and reprint with them, do it again,” Dr Dagher said.  



<h3 class="wp-block-heading" id="h-fof-1-0-sits-at-the-center-of-a-new-research-center-in-maine">FoF 1.0 sits at the center of a new research center in Maine</h3>



With two immensely powerful machines, the University of Maine can develop biobased, locally sourced feedstocks, print affordable homes, and meet national security demands quickly. 



The University of Maine System Chancellor Dannel Malloy called it an intersection of engineering and computing that will “accelerate solutions that strengthen the state’s economy and communities.”



The FoF 1.0 <a href="https://interestingengineering.com/innovation/mit-3d-printer" target="_blank" rel="dofollow">3D printer</a> is only the beginning. Set to open this summer, the Green-Engineering and Material Factory of the Future (GEM) will break new ground as a 47,000 square foot manufacturing innovation center. 



Creating sustainable manufacturing practices and filling a much-needed gap in the workforce is its objective. They intend to nurture the next generation of leaders through a sustainable model.



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The photomolecular effect could explain a long-standing discrepancy in climate science – the observed higher absorption of sunlight by clouds than conventional models predict.

Science shocker: Light can vaporize water without heat, says MIT study

MIT researchers discover light-induced water evaporation, unveiling the photomolecular effect. Lab device shown measures this phenomenon with laser beams.

For millennia, humans have observed and utilized evaporation, the process by which water transforms from a liquid to a vapor. From witnessing the sun&#8217;s dry morning fog to extracting salt from evaporated seawater, this fundamental process has been a constant presence. However, a recent groundbreaking discovery by MIT researchers challenges our traditional understanding of evaporation. Their findings reveal that light, not just heat, plays a crucial role in driving this phenomenon.



<h3 class="wp-block-heading" id="h-light-triggered-evaporation">Light-triggered evaporation</h3>



This research, published in the journal <a href="https://www.pnas.org/doi/10.1073/pnas.2320844121" target="_blank" rel="noopener noreferrer nofollow" target="_blank">PNAS</a>, sheds light on a previously unknown mechanism – the photomolecular effect. The MIT team, led by Professor Gang Chen, demonstrated that light striking the water&#8217;s surface can directly liberate water molecules, causing them to evaporate into the air. This effect occurs independently of heat, upending our long-held belief that thermal energy is the sole driver of evaporation.



“I think this has a lot of applications,” Chen says. “We’re exploring all these different directions. And of course, it also affects the basic science, like the effects of clouds on climate, because clouds are the most uncertain aspect of climate models.”



The researchers meticulously conducted a series of experiments to validate this surprising phenomenon. They employed fourteen different tests and measurements, observing consistent evidence of light-induced evaporation across various conditions—notably, a key indicator involved measuring the air temperature above the water during evaporation under visible light. Instead of rising, the temperature plateaued, demonstrating that thermal energy wasn&#8217;t the cause.



<figure class="wp-block-image size-full"><img loading="lazy" decoding="async" width="900" height="600" src="https://cms.interestingengineering.com/wp-content/uploads/2024/04/image_ba571d.png" alt="" class="wp-image-60771" srcset="https://cms.interestingengineering.com/wp-content/uploads/2024/04/image_ba571d.png 900w, https://cms.interestingengineering.com/wp-content/uploads/2024/04/image_ba571d.png?resize=300,200 300w, https://cms.interestingengineering.com/wp-content/uploads/2024/04/image_ba571d.png?resize=768,512 768w" sizes="(max-width: 900px) 100vw, 900px" /><figcaption class="wp-element-caption">A lab device designed to measure the “photomolecular effect,” using laser beams. Credits: Bryce Vickmark/MIT</figcaption></figure>



Furthermore, the team observed variations in the evaporation rate based on the light&#8217;s angle, color, and polarization. These characteristics should be independent of heat-driven evaporation, yet the researchers documented these dependencies. For instance, the effect peaked at a 45-degree angle with green light, even though water minimally absorbs green wavelengths.



The researchers have proposed a theoretical explanation for the angle and polarization dependence. They suggest that light photons transfer sufficient force to water molecules at the surface, dislodging them from the liquid body. However, color dependence remains a mystery, requiring further investigation.



<h3 class="wp-block-heading">Repercussions for climate science and beyond</h3>



This discovery holds immense significance for various fields. Unaffiliated with the study, Professor Xiulin Ruan of Purdue University emphasizes its potential impact on understanding light-water interactions in clouds, fog, and natural water bodies, ultimately influencing <a href="https://interestingengineering.com/science/europe-fastest-warming-continent" target="_blank" rel="dofollow">weather and climate</a>. 



The photomolecular effect could explain a long-standing discrepancy in climate science – the observed higher absorption of sunlight by clouds than conventional models predict. This discrepancy has been a subject of debate due to the complexity of cloud measurements. Chen suggests the newly discovered mechanism might account for this excess absorption, potentially improving cloud-related climate calculations.



“Those experiments are based on satellite data and flight data,“ Chen explains. “They fly an airplane on top of and below the clouds, and there are also data based on the ocean temperature and radiation balance. And they all conclude that there is more absorption by clouds than theory could calculate.&#8221; &#8221; However, due to the complexity of clouds and the difficulties of making such measurements, researchers have been debating whether such discrepancies are real or not. And what we discovered suggests that hey, there’s another mechanism for cloud absorption, which was not accounted for, and this mechanism might explain the discrepancies,” Chen adds. 



The team&#8217;s experiments with LEDs illuminating an artificial cloud chamber observed fog heating, contradicting expectations as water doesn&#8217;t absorb visible light thermally. The photomolecular effect offers a more plausible explanation for this observation.



<h3 class="wp-block-heading">Potential applications and future directions</h3>



Beyond its scientific significance, the photomolecular effect presents exciting practical possibilities. Companies have already approached the research team, envisioning applications in areas like syrup evaporation and paper drying. Solar <a href="https://interestingengineering.com/culture/barcelona-drought-floating-desalination-plant" target="_blank" rel="dofollow">desalination systems</a> and industrial drying processes are prime candidates for harnessing this effect. Since drying consumes significant industrial energy, optimizing this process using light holds immense promise.



Professor Chen acknowledges the nascent stage of this discovery, highlighting the need for further exploration. The team recognizes the vast number of variables to consider, encompassing a deeper understanding of water and its potential application to other materials, both liquids and solids.



This research has garnered praise from the scientific community. Professor Shannon Yee of Georgia Tech applauds the work for introducing a new physical mechanism, prompting a reevaluation of our understanding of evaporation kinetics. Professor Janet Elliott of the University of Alberta commends the study&#8217;s meticulous approach and the potential for significant practical and scientific advancements.

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This discovery predates the previously established earliest occurrence of bioluminescence in animals by nearly 300 million years.

Bioluminescence 1st emerged in marine invertebrates 540 million years ago

Bamboo octocoral displaying bioluminescence

Scientists from the Smithsonian’s National Museum of Natural History have uncovered a key information about the origins of bioluminescence in animals. They have determined that this unique ability, which allows organisms to emit light through chemical reactions, emerged at least 540 million years ago in a group of marine invertebrates known as octocorals. 



This discovery significantly predates the previously established earliest occurrence of bioluminescence in animals by nearly 300 million years. The findings provide valuable insights into the evolution of this remarkable trait and may offer clues as to why it evolved in the first place. 



“Nobody quite knows why it first evolved in animals,” said Andrea Quattrini, the museum’s curator of corals and senior author of the study.



<h3 class="wp-block-heading" id="h-the-origins-of-bioluminescence">The origins of bioluminescence</h3>



To uncover the earliest origins of bioluminescence, the researchers delved into the evolutionary past of octocorals, a group of ancient animals known for frequently exhibiting this luminous trait. Octocorals include various creatures like soft corals, sea fans, and sea pens. Unlike hard corals, which create hard skeletons, octocorals form softer structures for shelter. Interestingly, octocorals usually emit light when they are disturbed, adding a layer of mystery to the exact purpose of their bioluminescent ability.



“We wanted to figure out the timing of the origin of bioluminescence, and octocorals are one of the oldest groups of animals on the planet known to bioluminesce,” lead author Danielle DeLeo said. “So, the question was, when did they develop this ability?”



“If we know these species of octocorals living today are bioluminescent, we can use statistics to infer whether their ancestors were highly probable to be bioluminescent or not,” Quattrini explained. “The more living species with the shared trait, the higher the probability that as you move back in time that those ancestors likely had that trait as well.



<h3 class="wp-block-heading" id="h-ancestor-of-octocorals-likely-possessed-bioluminescent-capabilities">Ancestor of octocorals likely possessed bioluminescent capabilities</h3>



The researchers employed various statistical methods, all of which pointed to a significant finding: approximately 540 million years ago, the common ancestor of octocorals likely possessed bioluminescent capabilities. This discovery predates the previously recognized earliest instance of bioluminescence in animals by a staggering 273 million years, overturning previous assumptions.



DeLeo and Quattrini noted that the large number of octocoral species, along with their relatively frequent bioluminescence, indicates that this trait may have played a crucial role in the group&#8217;s evolutionary success. However, the exact purpose of bioluminescence in octocorals remains a puzzle. Nonetheless, the fact that this trait has persisted for such a long time underscores its importance in their communication and survival strategies.



Beyond unveiling the origins of bioluminescence, this study provides valuable evolutionary insights with implications for the conservation and management of octocorals today. These organisms face numerous threats, including climate change and human activities such as fishing, oil and gas extraction, spills, and increasingly, marine mineral mining.



The study was published in <a href="https://doi.org/10.1098/rspb.2023.2626" target="_blank" rel="noopener noreferrer nofollow" target="_blank">Proceedings of the Royal Society B</a>.

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Adorned with vibrant hues, the poisonous moth stands out conspicuously, unlike other moth species.

This love story has a toxic twist: Bella moths use poison to attract mates

Bella moths have an old and unique wing pattern symmetry that makes them easily distinguishable from their close relatives.

Out of all the myriad ways that species in the animal kingdom use to attract mates—birds display brilliantly colored plumage, insects make music, bees do dances, glow worms use light, and the pufferfish goes as far as creating geometric circles in the seabed—none is truly as strange as the one displayed by the bella moth.



According to a recent study, the bella moth (Utetheisa ornatrix) has reportedly evolved to use the toxins of a particular plant they consume during caterpillarhood to not only safeguard themselves (and later their eggs) against predators but also attract potential mates.



The leaves and seeds of the rattlebox plant are laden with a particular kind of bitter-tasting toxin known as pyrrolizidine alkaloids. Widely shunned by the rest of the foragers, the rattlebox is the preferred food source of the bella moth. Not only does this brightly colored moth have immunity against this toxin—which, mind you, is one of the leading causes of accidental poisoning-related deaths in cattle—it can actually metabolize and use it to achieve its own ends.



Bella moths are prevalent across large parts of eastern North America, Central America, and the Caribbean, and they exhibit diurnal activity patterns. Unlike many other nocturnal species that rely on darkness for concealment from predators, bella moths deliberately flaunt their presence. Adorned with vibrant hues like radiant pink, pearl, onyx, and sulfur yellow scales on their wings, they stand out conspicuously, easily catching the attention of birds and carnivorous insects from afar. Any predator that attempts to prey upon a bella moth soon realizes its error.



“Banana spiders will cut them out of their webs,” explains study co-author Andrei Sourakov. “When caught, they produce foaming liquid that tastes bad made almost entirely out of alkaloids.” He also points out how wolf spiders and birds, common moth predators, do everything possible to avoid this poisonous moth.



<h3 class="wp-block-heading" id="h-how-bella-moths-use-poison-to-attract-mates">How bella moths use poison to attract mates</h3>



When female bella moths are ready to mate, they emit a cloud of aerosolized alkaloids acquired from the plants they consume as caterpillars. Males, drawn to this scent, reach the female and engage in a brief yet intricate ritual. During this ritual, they delicately touch the female&#8217;s head with two fluffy and retractable structures resembling dandelions. Each filament of these structures contains pyrrolizidine alkaloids.



If the female deems the male&#8217;s alkaloid supply sufficient in quantity and quality, they proceed to mate. After mating, the male leaves behind a spermatophore containing sperm and additional alkaloids. The female uses these compounds and alkaloids from her own reserves to imbue the resulting eggs with toxins.



Such biparental egg protection is uncommon among insects. Initially observed in bella moth adults in 1989, it represents the sole known instance of a male moth or butterfly investing chemical resources in its offspring.



This study was published in the journal <a href="https://www.pnas.org/doi/abs/10.1073/pnas.2319726121" target="_blank" rel="noopener noreferrer nofollow" target="_blank">PNAS</a>.

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This new chip will adopt a three-part approach to protect AI devices from data attacks.

MIT&#8217;s new powerful chip thwarts millions of data theft attacks in tests

The new chip can efficiently accelerate machine-learning workloads on edge devices like smartphones while protecting sensitive user data from attacks. 

A team of researchers from MIT and the MIT-IBM Watson AI Lab has developed a new chip to make health-monitoring apps more secure. These new machine-learning accelerator chips aim to enhance data security for health trackers, fitness apps, and other AI-powered devices.



Health-monitoring apps offer powerful fitness-tracking tools that help people manage chronic conditions and wellness goals.&nbsp;



To function properly, these apps rely on machine learning models, where constant communication between the phone and a central server and extensive data exchange occur.&nbsp;



Due to this constant communication process, such apps slow and drain a device’s battery. Therefore, engineers often use machine-learning accelerators, specialized hardware that speeds up the process.&nbsp;



However, these accelerators leave devices open to crack, making these apps vulnerable to data theft as hackers can steal sensitive health and financial data.



<h3 class="wp-block-heading" id="h-safe-design-to-maintain-privacy">Safe design to maintain privacy</h3>



The new machine-learning accelerator is designed to resist the most common types of attacks per <a href="https://interestingengineering.com/innovation/mit-ai-predict-human-actions" rel="dofollow">MIT</a>. It involves several clever optimizations to maximize security while minimizing the impact on speed and accuracy. 



It aims to maintain the privacy of sensitive user data while allowing large AI models to run seamlessly on devices. 



“It is important to design with security in mind from the ground up. If you are trying to add even a minimal amount of security after a system has been designed, it is prohibitively expensive,” said Maitreyi Ashok, an electrical engineering and computer science (EECS) graduate student at MIT.



However, implementing these chips would make a device more expensive and less energy-efficient, Ashok added.&nbsp;



“We were able to effectively balance a lot of these tradeoffs during the design phase.”



<h3 class="wp-block-heading" id="h-critical-in-future-mobile-devices">&#8216;Critical in future mobile devices&#8217;</h3>



The key to enhanced security through these new machine-learning accelerators lies in a three-part approach.&nbsp;At first, the chip splits data into random fragments. This prevents hackers from reconstructing meaningful information through what are known as &#8220;side-channel attacks.&#8221;&nbsp;



Thereafter, it employs a lightweight cipher to encrypt the AI model stored in off-chip memory, making &#8220;bus-probing attacks&#8221; ineffective. Finally, a unique decryption key is generated directly on the chip based on tiny manufacturing variations, making it nearly impossible for hackers to duplicate it.



“As security has become a critical issue in the design of edge devices, there is a need to develop a complete system stack focusing on secure operation,&#8221; said Anantha Chandrakasan, MIT&#8217;s Chief Innovation Officer. &#8220;This work focuses on security for machine-learning workloads and describes a digital processor that uses cross-cutting optimization, added Chandrakasan. 



He further added that the device generates &#8220;unique codes&#8221; through randomization and variability and secures data access between the processor and memory to prevent side-channel attacks. &#8220;Such designs are going to be critical in future mobile devices,” concluded Chandrakasan, who also serves as the dean of the School of Engineering and Vannevar Bush Professor of Electrical Engineering and Computer Science. 



<h3 class="wp-block-heading" id="h-rigorous-tests-result-in-effective-outcome">Rigorous tests result in effective outcome</h3>



The researchers subjected this new chip to intensive testing, simulating real-world hacking attempts, and the results were impressive.&nbsp;&nbsp;



Even after millions of attempts, they were unable to recover any private information. In contrast, stealing data from an unprotected chip took only a few thousand samples.



This advancement has far-reaching implications. While the immediate focus is on health apps, secure machine-learning accelerators could power demanding <a href="https://interestingengineering.com/science/vasa-1-microsofts-new-ai-tool" rel="dofollow">AI applications</a> like augmented and virtual reality or autonomous driving, all while prioritizing the secure handling of user data.



Moving forward, the researchers plan to explore ways to minimize the energy and size impact of their chip, making widespread implementation more feasible.

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A team at Texas A&amp;M University is focusing on MXenes, which is expected to be a compelling alternative to conventional lithium-ion batteries.

MXenes to revolutionize energy storage; may help devices charge in seconds

Representative image of energy storage devices

A team at Texas A&amp;M University is taking significant steps for the development of a new generation of energy storage devices. They aim to develop a device that can combine the benefits of current technologies while addressing their limitations. <a href="https://engineering.tamu.edu/news/2024/04/improved-energy-charged-in-seconds-powered-for-days.html" target="_blank" rel="noopener noreferrer nofollow" target="_blank">Dr. Abdoulaye Djire</a>, a chemical engineering professor at Texas A&amp;M University, as well as a few chemistry engineering graduates are focusing on MXenes, which is expected to be a compelling alternative to conventional lithium-ion batteries. Currently, the team is exploring the major advantages of nitride MXenes. &#8220;We hope this work paves the way to the development of energy storage devices that can be fully charged within seconds and that can last for days,&#8221; said Djire.



<h3 class="wp-block-heading" id="h-rapid-charging-and-extended-lifespan">Rapid charging and extended lifespan</h3>



“There&#8217;s a lot of work that remains to be done prior to the full realization of this energy storage technology. This is the first step of more exciting research that we&#8217;re going to be doing here at Texas A&amp;M,&#8221; said Djire. The team will further study the charge storage mechanisms of the nitride MXenes to optimize their performance to meet future energy storage demands.&nbsp;&nbsp;



Djire expects that their ongoing research will have a major impact across various domains reliant on energy storage solutions.



<h3 class="wp-block-heading" id="h-about-mxenes">About MXenes</h3>



MXenes are two-dimensional materials that consist of titanium and carbon atoms. Their outstanding mechanical strength, ultrahigh surface-to-volume ratio, and superior electrochemical stability make them promising candidates as supercapacitors—that is, as long as they can be arranged in 3D architectures where there is a sufficient volume of nanomaterials and their large surfaces are available for reactions, reported <a href="https://phys.org/news/2023-11-2d-3d-mxene-path-revolutionizing.html" target="_blank" rel="noopener noreferrer nofollow" target="_blank">Physics.org.</a>



<h3 class="wp-block-heading" id="h-difficult-to-use-on-the-mass-scale">Difficult to use on the mass scale</h3>



Two-dimensional materials are crystals that have one or more layers, all atoms of which are located in the surface layer. This makes them highly <a href="https://globalenergyprize.org/en/2024/04/12/mxenes-for-energy-storage-new-way-of-producing-two-dimensional-materials/" rel="noopener noreferrer nofollow" target="_blank">chemically active</a> and, as a result, easy to use as electrodes—devices that conduct electric current. However, the synthesis of two-dimensional materials requires expensive equipment, making them difficult to use on a mass scale. With its layered structures, MXenes enhance electrolyte ion transport and give transition metal active redox sites on the surface. These features make MXenes particularly promising for applications as high-performance electrodes for electrochemical capacitors (supercapacitors).

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The photographer developed film using several substances, including blood and urine.

Photographer develops film using weed, in a world&#8217;s first

This “4/20” (April 20), an international day celebrating the smoking of cannabis, was made memorable by Dmitri Tcherbadji, a photographer in Vancouver, Canada.&nbsp;



Dmitri, who writes for the Analog Cafe website, conducted a unique photography experiment using <a href="https://interestingengineering.com/culture/germany-decriminalizes-cannabis" rel="dofollow">cannabis</a>. He has created the world’s first film developer made from cannabis flowers, which he calls “Sativa Cannanol.”



This development is interesting considering that, traditionally, black-and-white film development relies on commercially produced chemicals. Besides, photographers typically use alternative, homemade developers such as Caffenol, made with instant coffee.&nbsp;



The use of cannabis in this process is entirely new and sheds light on the potential of this plant for non-traditional applications.



<h3 class="wp-block-heading" id="h-an-intriguing-experiment">An intriguing experiment</h3>



Intrigued by the idea that film can be developed with various organic substances, Dmitri decided to <a href="https://interestingengineering.com/health/can-cannabis-help-address-the-opioid-crisis-new-study-investigates" rel="dofollow">experiment with cannabis</a>. He believes he might be the first person to ever develop 35mm film using cannabis.



For context, Caffenol, a developer made from coffee, vitamin C, and baking soda, is one of the best-known homemade options. Some photographers have also explored recipes using beer, wine, garlic, and other surprising ingredients.



Dmitri is inclined towards cannabis for two key factors. Firstly, cannabis is rich in phenols, which are chemical compounds commonly used in film developers. Secondly, with legalization becoming more widespread, particularly in Canada, the photographer saw an opportunity to explore cannabis for a unique purpose.



<figure class="wp-block-embed is-type-video is-provider-youtube wp-block-embed-youtube wp-embed-aspect-16-9 wp-has-aspect-ratio"><div class="wp-block-embed__wrapper">
<iframe loading="lazy" title="Can You Develop Film in ANYTHING?" width="500" height="281" src="https://www.youtube.com/embed/JjMStAcKlqQ?start=195&#038;feature=oembed" frameborder="0" allow="accelerometer; autoplay; clipboard-write; encrypted-media; gyroscope; picture-in-picture; web-share" referrerpolicy="strict-origin-when-cross-origin" allowfullscreen></iframe>
</div></figure>







“It turns out that cannabis sativa strains are rich in phenols, making the plant an ideal candidate for film development,” Dmitri says. He further notes that you only need 1.5g of cannabis to make a 300ml solution, far less than the coffee used in Caffenol.



To expand his experiment, he collaborated with fellow photographers Daren (@LearnFilmPhotography) and Yvonne (@YvonneHansonPhotography). Together, they developed film using a bizarre mix of substances: blood, pond water, wood, flowers, and even urine.



<h3 class="wp-block-heading">Unique results</h3>



Believing that cannabis could be a viable developer, Dmitri embarked on a series of tests. He documented his process, including using different cannabis strains in various &#8220;Sativa Cannanol&#8221; recipes.&nbsp;



He carefully shot over 200 photos in a studio setting using a Pentax K1000 camera and then used the Sativa Cannanol developer on Ilford HP5+ film. The photographer immersed the film rolls for 420 seconds at 69 degrees Fahrenheit.



Dmitri even managed to reuse the developer several times, although he noted a slight decrease in quality with each use.



<h3 class="wp-block-heading">The cost factor and significance</h3>



However, these new cannabis-based film developers are not cost-effective. Dmitri accepts he ended up paying around $7 to develop a single roll of film.



&#8220;But you can certainly create detailed, well-resolving images with cannabis if you’re inclined to do so,&#8221; said the photographer.



Dmitri has shared his Sativa Cannanol recipes on his website, so that other photographers can also do this experiment or do further research.

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Able to absorb carbon emissions as a tree and oil as a laser-treated sheet, cork just might be an environment superhero.

Trash to titan: Scientists create laser-treated cork that absorbs oil spills

An oil skimming operation works in a heavy oil slick in Valdez, Alaska, a week after the Exxon Valdez oil spill disaster, on April 1, 1989. 

The Office of Response and Restoration responds to 150 oil and chemical spills every year. Most of these might be small, but they impact the environment across the board: up into the atmosphere and down to the ocean bottom. 



Though the number of oil spills may have decreased since the 1990s, about 3,000 metric tons were reported to have spilled in 2023. Currently, chemical dispersion is the primary method to remove oil from water, but these chemicals are toxic. Thus, it is imperative to find a better solution to clean it up as fast as possible.



That was the plan for a group of researchers from Central South University, Huazhong University of Science and Technology, and Ben-Gurion University of the Negev. And they found an ingenuous solution by accident: cork. 



<h3 class="wp-block-heading" id="h-a-laser-treated-cork-that-can-absorb-oil-and-repel-water">A laser-treated cork that can absorb oil and repel water</h3>



While conducting a laser experiment, they discovered that cork became a superhero with “superhydrophobic [water-repelling] and superoleophilic [oil-attracting] properties,” Yuchun He said.



“After appropriately adjusting the processing parameters [with a laser], the surface of the cork became very dark, which made us realize that it might be an excellent material for photothermal conversion.”



In a study just published, researchers tested the cork with a fast-pulsing laser— all low-cost—at a variety of frequencies to arrive at the perfect balance of properties that make it an optimal oil-removing material on water.



They measured <a href="https://interestingengineering.com/energy/quantum-material-solar-cells" target="_blank" rel="dofollow">nanoscopic changes</a> in the material&#8217;s structure, the ratio of oxygen and carbon, as cork already absorbs carbon, a main ingredient in oil. They even studied the &#8220;changes in the angles at which water and oil contact the surface, and the material’s light wave absorption&#8221; to arrive at a basic but stunning solution: Just lay a sheet of this super water-repellant cork and take the oil out of the ocean.



<h3 class="wp-block-heading" id="h-could-laser-treated-cork-help-clean-up-the-air-too">Could laser-treated cork help clean up the air, too? </h3>



As a porous material, cork absorbs sunlight and heat at a fast rate. Even a little sunlight can heat the material in as little as 10-15 seconds. In turn, that heats the oil beneath it, which makes it easier to collect. 



In their experiments, this laser-treated cork soaked up oil out of water in two minutes. Even more amazingly, treating it with a <a href="https://interestingengineering.com/science/quantum-state-room-temp-magnetism" target="_blank" rel="dofollow">fast-pulsing laser </a>makes it particularly water-repellant, so the oil could be recycled and reused, they found. 



“Combining these results with the eco-friendly, recyclable advantages of cork, we thought of using it for marine oil spill cleanup,” author Kai Yin said. “To our knowledge, no one else has tried using cork for cleaning up marine oil spills.”



On top of it, could planting more cork oak trees help tackle carbon emissions? 



Cork derives itself from the bark of cork oak trees with a life span of hundreds of years. Able to be harvested every seven years, cork is a renewable material. In fact, removing the bark even triggers these trees to amp up their cork production and increase their carbon storage, so “harvesting cork helps mitigate carbon emissions.” 



That could be an exciting by-product of this discovery as carbon emissions threaten the environment due to fossil fuels. Cork oak trees seem to become more powerful when harvested. And we can use the same trees for hundreds of years. Nothing but advantages. <a href="https://interestingengineering.com/innovation/bebot-robot-belle-isle-pollution" target="_blank" rel="dofollow">Yet another solution to tackle pollution</a>.



The next step for these researchers “is to prepare electrothermal materials using polyurethane foam as the skeleton for oil adsorption, combining photothermal and electrothermal techniques to form an all-weather oil recovery system.” 



They just published their study in&nbsp;<a href="https://aip.scitation.org/journal/apl" target="_blank" rel="noopener noreferrer nofollow" target="_blank">Applied Physics Letters</a>.

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It would have created thousands of pieces of space shrapnel, leading to a destructive cascading effect in low Earth orbit.

Terrifying near-miss: Russian space junk almost destroys NASA satellite

The space debris problem continues to grow.



A new analysis of a near-miss for NASA’s TIMED satellite in February shows that debris came much closer than previously thought.



The new update adds to the growing list of close calls and raises alarm over the increasing frequency of these events.



<h3 class="wp-block-heading" id="h-nasa-timed-satellite-s-close-encounter">NASA TIMED satellite’s close encounter</h3>



In late February, space shrapnel from the defunct Russian Cosmos 2221 satellite narrowly missed NASA’s TIMED spacecraft. TIMED is an operational satellite tasked with studying the Mesosphere and Lower Ionosphere.



Had the two collided, it would have created thousands of tiny pieces of space debris. After that, this debris would have continued to fly around Earth’s orbit at tens of thousands of miles per hour. They could then smash and fragment other satellites or pieces of space junk, creating a cascading effect known as <a href="https://interestingengineering.com/science/kessler-syndrome-spacex-starlink-orbital-chaos" rel="dofollow">Kessler Syndrome</a>.



Initial observations suggested the two satellites came within 20 meters of each other. However, a NASA official recently revealed that it was much closer.



During the 39th Space Symposium in Colorado Springs earlier this month, NASA Deputy Administrator Pam Melroy said, “We recently learned through analysis that the pass ended up being less than 10 meters [33 feet] apart — within the hard-body parameters of both satellites.&#8221;



&#8220;It was very shocking personally, and also for all of us at NASA,&#8221; Melroy was quoted as saying by <a href="https://www.space.com/nasa-timed-satellite-russian-space-junk-near-miss-february-2024" rel="noopener noreferrer nofollow" target="_blank">Space.com</a>. The near miss &#8220;really scared us all,&#8221; she added.



Crucially, both TIMED and the defunct defense satellite Cosmos 2221 are non-maneuverable, meaning NASA was not able to alter its satellite’s trajectory as a precautionary measure. In recent years, for example, it has had to alter the International Space Agency’s trajectory to avoid space junk created by a Russian weapon test.



<h3 class="wp-block-heading" id="h-the-cascading-space-debris-problem">The cascading space debris problem</h3>



Space debris is a growing problem for the global astronomical community as well as for the satellite industry. It is even becoming more of a problem on Earth, as space debris recently <a href="https://interestingengineering.com/space/nasa-owns-space-junk-that-tore-through-florida-house-almost-hit-a-boy" rel="dofollow">tore through</a> the roof of a Florida house in March.



“Had the two satellites collided, we would have seen significant debris generation – tiny shards traveling tens of thousands of miles an hour, waiting to puncture a hole in another spacecraft, potentially putting human lives at risk,” Melroy explained.



There are over 27,000 pieces of space debris in orbit, and this number will continue to grow as the rate of satellite launches far outpaces any efforts at building debris removal technology.



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FuZe is a low-cost and compact device that can reach fusion energy temperatures rapidly and cater to our energy needs sooner.

US startup&#8217;s fusion energy device reaches 37-million-degree temperature

A bright flash of light from a FuZE (Fusion Z-pinch Experiment) plasma.

A small-scale and compact device built by US-based fusion startup Zap Energy has achieved plasma electron temperatures of 1-3 keV, roughly equivalent to 20 to 66 million degrees Fahrenheit (11 to 37 million degrees Celsius). 



In nearly a century of humanity working with fusion reactions, only a few technologies have reached plasma fusion temperatures above 27 million degrees Fahrenheit (15 million degrees Celsius), the temperature of our Sun&#8217;s core. 



With the world looking for cleaner ways of meeting its <a href="https://interestingengineering.com/culture/sam-altman-ai-nuclear-fusion" target="_blank" rel="dofollow">energy demands</a>, nuclear fusion is considered a responsible way to generate large amounts of energy. 



<h3 class="wp-block-heading" id="h-plasma-and-nuclear-fusion">Plasma and nuclear fusion</h3>



The first step of the process is the generation of plasma &#8211; the fourth state of matter where nuclei and electrons do not maintain their atomic state but float freely. 



This fusion of the atoms gives out 10 million times more energy per ounce than burning the same amount of coal. However, since the fusion plasma consists of two components (nuclei and electrons) that vary significantly in their masses, they heat and cool at different rates. 



The rapidly cooling electrons can limit the plasma&#8217;s heating, a hurdle in the development of fusion reactors.  



<h3 class="wp-block-heading" id="h-fuze-plasma">FuZe plasma</h3>



The Department of Energy&#8217;s Advanced Research Projects Agency-Energy (ARPA-E) funded the prior work in this space at the University of Washington. 



Out of this research, Zap Energy was spun off in 2020 and it uses a plasma confinement scheme called the Fusion Z-pinch Experiment (FuZe) to ensure that electrons do not cool rapidly. 



In this approach, large electric currents are channeled through thin plasma filaments, generating the plasma&#8217;s electromagnetic fields that heat it while compressing it.&nbsp;



The problem with this approach, however, was that the resultant plasmas were short-lived. Zap Energy has addressed this by applying a dynamic flow through the plasma, a process called sheared-flow stabilization.&nbsp;



&#8220;The dynamics are a wonderful balancing act of plasma physics,&#8221; said Ben Levitt, Vice President of R&amp;D at Zap. &#8220;As we climb to higher and higher plasma currents, we optimize the sweet spot where the temperature, density and lifetime of the Z pinch align to form a stable, high-performance fusing plasma.&#8221;



<figure class="wp-block-image size-full"><img loading="lazy" decoding="async" width="700" height="467" src="https://cms.interestingengineering.com/wp-content/uploads/2024/04/low-res_4eae52.jpg" alt="FuZe experimental setup" class="wp-image-60346" srcset="https://cms.interestingengineering.com/wp-content/uploads/2024/04/low-res_4eae52.jpg 700w, https://cms.interestingengineering.com/wp-content/uploads/2024/04/low-res_4eae52.jpg?resize=300,200 300w" sizes="(max-width: 700px) 100vw, 700px" /><figcaption class="wp-element-caption">FuZe has reached temperatures of 30 million degrees and above without using superconducting magnets or lasers. Image credit: <a href="https://www.eurekalert.org/multimedia/1022526" rel="noopener noreferrer nofollow" target="_blank">Zap Energy</a>. </figcaption></figure>



<h3 class="wp-block-heading">Record temperatures</h3>



Researchers can now measure the temperature of the nuclei and electrons in plasma&#8217;s hot sub-atomic soup separately. Zap Energy teamed up with researchers at the Lawrence Livermore National Laboratory (LLNL) and the University of California, San Diego (UCSD) to measure the temperature of the electrons from FuZe. 



In an approach called Thomson scattering, the researchers fired bright pulses of green light at the plasma very fast. They measured the scattering of the electrons and their temperature. 



The measurements confirmed that electrons in the FuZe plasma were as hot as the nuclei, and the plasma maintained a healthy thermal equilibrium. 



Unlike other fusion techs being experimented with, FuZe does not need <a href="https://interestingengineering.com/energy/new-superconducting-magnets-ready-for-fusion-reactions-say-scientists" target="_blank" rel="dofollow">superconducting magnets</a> or powerful lasers to generate its plasma, making it a very cost-effective approach. 



&#8220;Zap tech is orders of magnitude less expensive and quicker to build than other devices, allowing us to iterate rapidly and produce the cheapest thermal fusion neutrons out there,&#8221; said Benj Conway, CEO and co-founder of Zap, in the press release. &#8220;Compelling innovation economics are vital to launching a commercial fusion product on a timescale that matters.&#8221;



Results from the FuZe were published in the journal <a href="https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.132.155101" target="_blank" rel="noopener noreferrer nofollow" target="_blank">Physical Review Letters</a>. 



Interestingly, the team has commissioned its next project, Fuze-Q, which has an energy capacity ten times bigger than FuZe and can reach much higher temperatures.&nbsp;

<ul>
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 	<li><a href="https://interestingengineering.com/energy/scientists-build-breakthrough-nuclear-fusion-device-with-household-magnets">Scientists build breakthrough nuclear fusion device with household magnets</a></li>
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</ul>

The E Performance hybrid drive system boasts an electric motor on the rear axle and a handcrafted AMG 4.0-liter V8 biturbo engine up front.

Mercedes-AMG&#8217;s latest GT rockets 0-60mph in 2.7 seconds

E Performance hybrid drive enables an 805 hp combined system output.

From zero to 60 miles per hour (0-95.5 kph) in just 2.7 seconds, no Mercedes AMG series model has ever sprinted that fast. 



The statistics hold for the German carmaker&#8217;s new flagship, the 2025 Mercedes-AMG GT 63 S E Performance, unveiled on the sidelines of Formula 1 in Shanghai. 



The incredibly potent E Performance hybrid drive system, which includes an electric motor on the rear axle and a handcrafted AMG 4.0-liter V8 biturbo engine up front, provides lightning-fast reaction and steady power delivery.



According to the company, the two-door coupe has also taken performance cues from vital technologies used in the Mercedes-AMG PETRONAS F1 Team&#8217;s hybrid race cars. 



The GT 63 S E Performance now holds the title of the brand&#8217;s fastest, surpassing the 1000-horsepower <a href="https://interestingengineering.com/transportation/mercedes-revealed-1000-hp-amg-one" target="_blank" rel="dofollow">AMG One&#8217;s</a> 2.9-second sprint. &#8220;Our four-liter V8, combined with the performance hybrid system, makes the vehicle the top model in our GT family,&#8221; said Michael Schiebe, CEO of Mercedes-AMG, in a <a href="https://media.mbusa.com/releases/world-premiere-of-the-new-flagship-mercedes-amg-gt-63-s-e-performance" target="_blank" rel="noopener noreferrer nofollow" target="_blank">statement</a>.



<h3 class="wp-block-heading" id="h-best-of-both-worlds">Best of both worlds </h3>



The handcrafted AMG 4.0-liter V8 biturbo engine and AMG Electric Drive Unit in the new AMG GT 63 S E Performance combine to produce 805 horsepower and a system torque of up to 1,047 lb-ft.



The system ensures that the car can go from 0 to 60 mph (0 to 95.5 kph) in just 2.7 seconds and has an electronically limited top speed of 199 mph (320 kph).



The electric drive unit (EDU) consists of a 201-horsepower permanently excited synchronous electric motor paired with an electrically shifted two-speed transmission and a limited-slip rear differential. 



A lightweight AMG high-performance <a href="https://interestingengineering.com/science/sodium-battery-charged-in-seconds" target="_blank" rel="dofollow">battery</a> powers the electric motor. The system is placed at the rear above the rear axle.&nbsp;This design holds significance in the overall dynamics of the car. 



The electric motor directly powers the rear axle, enhancing propulsion during acceleration, starting from a standstill or overtaking. In cases of rear wheel slip, the electric motor distributes power to the front wheels for added traction. 



This is facilitated by the AMG Performance 4MATIC+ fully variable all-wheel drive system, which utilizes the driveshaft and drive axles of the front wheels. Placing the motor on the rear axle improves weight distribution and enhances dynamic handling.



<h3 class="wp-block-heading" id="h-f1-inspired-battery-technology">F1-inspired battery technology</h3>



Maintaining consistent battery temperature is key for performance, longevity, and stability. Conventional cooling methods, like air or indirect water cooling, struggle to meet increasing demands with denser cells.



The 400-volt AMG High Performance Battery relies on an advanced direct cooling system. An electrically non-conductive liquid coolant circulates around its 560 cells, individually cooling them. 



This coolant has double to triple the heat capacity of water, ensuring efficient thermal energy storage. According to the firm, AMG&#8217;s thin 0.04-inch cooling shafts, matching cell height, enable direct cooling.



Drawing from the <a href="https://interestingengineering.com/innovation/mercedes-new-tech-lets-you-control-your-car-with-your-mind" target="_blank" rel="dofollow">Mercedes</a>-AMG PETRONAS F1 Team&#8217;s hybrid race car tech, the battery delivers high power repeatedly, enhancing the AMG GT Coupe&#8217;s overall performance. The firm claims that with rapid energy draw and high power density, it boasts a 6.1 kWh capacity, sustaining 94 hp continuously and peaking at 201 hp. 



Prioritizing swift power delivery over range, it charges via the onboard 3.7 kW AC charger at charging stations, wall boxes, or household sockets.



Also, derived from its racing cars, the operating strategy ensures instant power for aggressive acceleration, akin to F1 racing. Continuous electric power is ensured via efficient recuperation and tailored recharging, optimizing dynamic performance and efficiency.



Direct cooling maintains the battery at an ideal 113°F, enhancing recuperation efficiency. Recuperation starts upon releasing the accelerator, charging the battery, and providing braking torque, which acts like an engine brake on descents. 



Using the AMG Drive Unit button, the driver can select from four recuperation levels, offering up to 100 kW of energy recovery, similar to one-pedal driving in electric cars.



As with its previous edition, the model also features active roll stabilization, fully variable all-wheel drive, active rear-axle steering, and a carbon ceramic high-performance brake system. 



The 2025 AMG GT 63 S E Performance is expected to arrive at US dealerships in late 2024.

<div class="Review_header__rCaGD">
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 	<li class="content-title mt-3"><a href="https://interestingengineering.com/transportation/mercedes-revealed-1000-hp-amg-one">Mercedes finally revealed the 1,000-HP AMG ONE. And it’s a pricey speed demon</a></li>
 	<li class="content-title mt-3"><a href="https://interestingengineering.com/science/sodium-battery-charged-in-seconds">New sodium battery that can be charged in seconds developed</a></li>
</ul>
</div>
<div class="Review_desc__skOL9">
<div class="Review_desc__skOL9">
<div class="Review_desc__skOL9">
<h2 class="article-abstract"></h2>
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</div>

The great-grandson of renowned physicist has come up with a new technique for making time measurement more precise.

Superradiant atoms could lead to more accurate atomic clocks

The luminous ball in the middle, called a "magneto-optical trap" (MOT), consists of approximately 300 million strontium atoms suspended in a vacuum chamber cooled to just above absolute zero. This trap was used by researchers to develop new techniques for measuring time.

Eliot Bohr, the great-grandson of renowned physicist Niels&nbsp;Bohr, has come up with a new technique for making time measurement more precise than ever.&nbsp;



This new technique is based on “superradiant atoms” to accurately measure the time interval, specifically the seconds. It may help overcome some limitations faced by the currently used advanced <a href="https://interestingengineering.com/innovation/optical-clock-accurate-billions-of-years" rel="dofollow">atomic clocks.</a> 



<h3 class="wp-block-heading" id="h-overcoming-current-limitations">Overcoming current limitations</h3>



Currently, there are over 400 atomic clocks located worldwide. These clocks together play an important role in calculating accurate time. Oscillations are one of the most essential factors in keeping precise time.



These clocks use the oscillations of atoms — typically cesium or rubidium atoms — to measure time intervals with extreme precision.



Moreover, atomic clocks use radio waves to constantly synchronize various devices, including computers, phones, and wristwatches.



As per the press release, these modern atomic clocks rely on lasers to measure oscillations in strontium atoms, but this process generates heat, which reduces precision.



&#8220;Because the atoms constantly need to be replaced with fresh new atoms, while new atoms are being prepared, the clock loses time ever so slightly,&#8221; explained Eliot Bohr, a PhD fellow at the University of Colorado.



&#8220;Therefore, we are attempting to overcome some of the current challenges and limitations of the world’s best atomic clocks by, among other things, reusing the atoms so that they don’t need to be replaced as often.&#8221; 



<h3 class="wp-block-heading" id="h-this-method-could-benefit-gps">This method could benefit GPS </h3>



Bohr and his colleagues devised a novel way of reading out atoms.



&#8220;When the atoms land in the vacuum chamber, they lie completely still because it is so cold, which makes it possible to register their oscillations with the two mirrors at opposing ends of the chamber,&#8221; said Eliot Bohr.  



The team harnesses a quantum physical phenomenon called superradiance, which takes place when the strontium atom group becomes entangled and emits light in the field between the two mirrors.



&#8220;The mirrors cause the atoms to behave as a single unit. Collectively, they emit a powerful light signal that we can use to read out the atomic state, a crucial step for measuring time,&#8221; stated Bohr.



Bohr further asserted, &#8220;This method heats up the atoms minimally, so it all happens without replacing the atoms, and this has the potential to make it a more precise measurement method.&#8221; 



This new research could be used to develop a more accurate GPS. Satellites are outfitted with atomic clocks to give accurate GPS settings on phones.&nbsp;



That is why these atomic clocks must operate with remarkable precision. Bohr highlighted that even if the atomic clock is wrong by a microsecond, it will result in an error of around 100 meters on Earth&#8217;s surface. 



Atomic clocks with high precision could be used in future deep <a href="https://interestingengineering.com/lists/10-space-missions-upcoming-2024" rel="dofollow">space missions</a> for navigation purposes.&nbsp;



This is not all. Advanced and precise atomic clocks can be used for purposes other than timekeeping.



&#8220;Atomic clocks are sensitive to gravitational changes and can therefore be used to detect changes in Earth&#8217;s mass and gravity, and this could help us predict when volcanic eruptions and earthquakes will occur,&#8221; Bohr concluded in the <a href="https://via.ritzau.dk/pressemeddelelse/13808173/superradiant-atoms-could-push-the-b[…]ow-precisely-time-can-be-measured?publisherId=13561218&amp;lang=da" rel="noopener noreferrer nofollow" target="_blank">press release.</a>



The team highlights that this technique is currently a &#8220;proof of concept&#8221; and needs further improvisation. 



The study has been published in the journal <a href="https://www.nature.com/articles/s41467-024-45420-x" rel="noopener noreferrer nofollow" target="_blank">Nature Communications. </a>

<ul>
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</ul>

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New diamond wafers made in Japan can store 1 billion Blu-Ray discs of data

We are now one step closer to quantum computers that utilize diamond wafers.

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