Explore the most recent cutting-edge innovation from the Defense Advanced Research Projects Agency, commonly referred to as DARPA. Introducing a colossal uncrewed submarine inspired by the manta ray, created by the same innovators behind hypersonic air-breathing weapons, submarine-detecting shrimp, and robot jazz musicians. Northrop Grumman’s prototype has just finished its initial in-water trial.

The submarine has been designed to transport substantial loads across extensive distances beneath the water’s surface without the presence of any human occupants for assistance. During deployment, it can enter a state of “hibernation,” where it remains attached to the seabed in order to conserve energy.

In 2022, Northrop Grumman stated that their design for the project would serve DARPA’s objective of generating “strategic surprise.” We believe it is safe to assert that they have successfully accomplished that objective.

In February and March of this year, DARPA conducted a comprehensive test of the prototype uncrewed underwater vehicle (UUV) off the coast of Southern California.

“The successful and comprehensive testing of the Manta Ray confirms that the vehicle is prepared to progress towards real-world operations. It was quickly assembled in the field using modular subsections,” stated Dr. Kyle Woerner, the DARPA program manager for Manta Ray. The integration of cross-country modular transportation, on-site assembly, and subsequent deployment showcases a unique capability for an extra-large unmanned underwater vehicle (UUV).

The level of specificity we can currently provide is limited to “extra-large.”. New Atlas reports that DARPA and Northrop Grumman have thus far maintained confidentiality regarding the majority of the technical details of the aircraft. However, it is speculated that the online images reveal concealed propulsors, an antenna, water inlets, and potentially maneuvering thrusters.

By examining the images, we can gain an understanding of the size and observe that its sleek curves truly resemble the animal it is named after—and perhaps even a few science fiction creations as well.

Manta Ray #UUV prototype completes full-scale, in-water testing off the coast of SoCal. DARPA program exhibits modular, first-of-kind capability for an extra-large uncrewed underwater vehicle. Built by @northropgrumman. https://t.co/BIDfh3cZCD pic.twitter.com/t6dqWB3i33

— DARPA (@DARPA) May 1, 2024

Manta rays, which belong to numerous species, can be found in various bodies of water worldwide. Numerous reports of these creatures actively interacting with divers and snorkelers show that they are sociable and intelligent. However, it was the elegant movement of the manta rays that truly motivated the engineers responsible for the development of the new UUV, thus upholding a longstanding practice of drawing inspiration from nature for design purposes.

Following deployment, the vehicle navigates the water with effective buoyancy-powered gliding, according to Woerner.

An additional significant benefit of the Manta Ray UUV, emphasized by both DARPA and Northrop Grumman, is its capability to be transported in separate components and quickly reconstructed at the desired location. The prototype was transported from the build location in Maryland to the opposite side of the country and could also be useful in the field.

According to Woerner, transporting the vehicle directly to its intended area of operation helps to save energy that would otherwise be used during transit.

DARPA is presently collaborating with the US Navy to determine the subsequent actions for this technology. The exact timeline for the deployment of Manta Ray in actual water remains undisclosed.

A novel approach to diamond production eliminates the need for extreme temperatures and pressures, thus making it possible to create diamonds at a significantly reduced cost. The world of precise crystal manipulation, as depicted in the science fiction novel The Diamond Age, may be within reach sooner than anticipated.

Despite our knowledge of synthetic diamond production dating back to the 1950s, the prevailing method still involves subjecting materials to extreme temperatures of 1,300–1,600 °C (2,400–2,900 °F) and applying 50,000 atmospheres of pressure for a period of 5–12 days. This has been instrumental in meeting the industrial demand for diamonds as cutting instruments while also offering unique colors for those with a preference for rare hues. Nevertheless, the expense of the procedure is comparable to that of discovering natural diamonds, whether for industrial use or as high-quality gemstones, which allows the mining industry to persist.

There might be a significant shift on the horizon as a method to produce diamonds under normal atmospheric pressure has been unveiled. The temperatures remain high at 1,025 °C (1,877 °F), but even at this level, significant savings can be achieved compared to the current heat requirements.

Low-pressure diamonds were once considered a paradoxical concept. Natural diamonds form deep within the Earth’s mantle under immense pressure from layers of crust above, and many of them were created long before complex life forms existed. The synthetic version utilizes liquid metal catalysts, but high pressures in the gigapascal range are still deemed necessary.

Nevertheless, scientists at Korea’s Institute for Basic Science have challenged this notion by demonstrating that diamonds can be grown using a liquid metal alloy of gallium, iron, nickel, and silicon, even without applying significant pressure in a hydrogen/methane atmosphere. The carbon in the diamond is derived from methane.

“This groundbreaking achievement was made possible through human creativity, persistent dedication, and the collaborative efforts of numerous contributors,” Professor Rod Ruoff stated. He omitted a significant amount of trial and error, which the team at the Institute employed while fine-tuning the combination of metals and other variables. When the team switched to a smaller chamber, they were able to make real progress in a surprisingly short amount of time, even though making the diamond itself was a quick process.

After extensive research, it was discovered that the diamonds tend to form at the lower part of the liquid alloy consisting of 77.75 percent gallium, 0.25 percent silicon, and 11 percent each of iron and nickel. It’s not a ratio that comes to mind right away. In addition, seed particles are not necessary for the production of these synthetic diamonds, unlike traditional methods.

“One day, when I conducted the experiment, subsequently cooled the graphite crucible to solidify the liquid metal, and extracted the solidified piece, I observed a fascinating pattern resembling a rainbow that extended over a few millimeters on the bottom surface of this piece,” shared graduate student Yan Gong. “We discovered that the colors of the rainbow are caused by diamonds!”

The process typically takes around 10 to 15 minutes to initiate diamond formation, with growth ceasing after approximately 150 minutes. However, the team is actively exploring methods to address this limitation.

The diamonds produced thus far are of a smaller size, resembling a film rather than a precious gemstone. As a result, diamond companies do not need to be overly concerned at this point. That could potentially change if scientists discover ways to enhance the supersaturated carbon layer that comes before the formation of diamonds. The silicon vacancy, which is highly sought after for creating colored diamonds, can also be created by nitrogen impurities. This characteristic makes these diamonds perfect for conducting experiments in the field of quantum computing.

The exact reasons behind the desired outcome of this particular combination of metals and gases remain a subject of ongoing investigation. The resemblance between silicon and carbon bonds is believed to play a crucial role. It is possible that carbon clusters containing silicon atoms could act as precursors to diamonds.

Mass production rarely relies on the initial iteration of a process demonstrated in a laboratory. According to Ruoff, there are several lower melting point metals that could be beneficial in terms of cost reduction or in creating diamonds with specific shades or properties.

The study has been published in the prestigious journal Nature.

There is a significant shift taking place in the way we generate electricity, even in the areas where it faces strong opposition. Texas is a prime example of the remarkable progress in renewable power, with continuous record-breaking achievements despite facing opposition from influential individuals.

In February 2021, a severe cold snap placed immense strain on the Texas electricity grid, resulting in extensive blackouts that tragically resulted in the loss of life and brought the region perilously close to catastrophe. As expected, certain individuals quickly pointed fingers at wind power as the cause of the issues, despite the fact that the majority of the capacity loss occurred in gas-fired power stations. They were, however, accompanied by a large number of influential Texas politicians, including the governor, which strongly suggested that they would favor continuously operating energy sources.

Instead, there has been a remarkable increase in the installation of photovoltaic panels since then. In March, solar power surpassed coal as the leading source of electricity in Texas, marking a significant milestone.

According to the Institute for Energy Economic and Financial Analysis (IEEFA), the Electric Reliability Council of Texas (ERCOT), the main power grid for most Texans, used a significant amount of solar-generated electricity in March. The total consumption reached 3.26 million megawatt hours (MWh). In comparison, 2.96 million MWh were generated from coal, making the difference approximately 10 percent.

In March, solar production experienced a significant increase of 56 percent compared to the previous year. This growth was three times higher than the March that occurred after the devastating freeze.

IEEFA highlights a series of significant achievements. In March, solar energy accounted for over 10 percent of ERCOT’s electricity generation, marking a significant milestone. At the same time, coal’s contribution fell below 10 percent for the first time.

Even in January, solar power played a crucial role in preventing a system meltdown during a cold snap by meeting nearly a quarter of the demand in the middle of the day.

The records will continue to be broken. By the end of the year, Texas is projected to add over 7 gigawatts (GW) of solar capacity to its grid, representing a nearly 30% increase from current levels. Despite potentially less favorable weather conditions, next March is expected to bring even more significant growth in solar energy. Exciting developments are in the works for additional enhancements in 2025. According to the Energy Information Administration, a government agency, solar power is projected to surpass coal as the primary source of electricity in Texas for the entire year.

The demand in Texas is not experiencing significant growth to accommodate the surplus production, especially when considering the slower growth of wind power. Consequently, there is a need to eliminate something from the market. Up until now, the primary source has been coal, not gas. In 2017, approximately 30% of the energy consumed in Texas came from coal. This year, it might exceed 10 percent for the year, even though it dipped below in March, but if it does, it won’t be by a significant margin.

Texans have been known for their tendency to go big in everything they do, including their use of coal. However, times are changing. Last year, it consumed twice as much coal for electricity compared to any other state. The decrease in coal usage in Texas has outpaced the national average, although other states are also making significant progress.

Critics of renewable energy often claim that solar power is ineffective when the sun is not shining. However, it is worth noting that Texas is currently at the forefront of battery installation in the United States. Actually, it’s going above and beyond. When it comes to solar, Texas and America as a whole lag significantly behind China in absolute terms and many countries on a per capita basis. However, when it comes to large-scale battery systems that can store surplus energy during the day and discharge it in the evening, Texas is at the forefront of global innovation.

In a recent report, it was stated that Texas currently has 5.2 GW of operational battery storage, with projections indicating that this number will increase to 10.9 GW by the end of the year. Solar power will ensure that the lights stay on long into the night.

Renewable energy has faced opposition for years from skeptics who doubted its viability, only to be proven wrong time and time again by its success in various locations.

One of the main factors driving the rapid growth of solar energy in Texas, despite the challenges posed by a government that is not particularly supportive of renewable power, is its significantly lower cost compared to other alternatives. If that’s true in Texas, the largest source of fossil gas in the United States, it’s likely that other places will soon follow suit with the energy revolution.