Lockheed Martin's Next Generation Interceptor Program Advances Through Major Design Milestone

Lockheed Martin NGI Artist rendering of NGI.
Illustration Credit: Lockheed Martin

Lockheed Martin's Next Generation Interceptor (NGI) program executed its digital All Up Round (AUR) Preliminary Design Review (PDR), in partnership with the Missile Defense Agency (MDA), on September 29. The company remains on-plan to deliver NGI on an accelerated schedule for the warfighter.

NGI is part of the MDA's Ground-based Midcourse Defense (GMD) system and will provide a new, advanced interceptor to protect the homeland against long range ballistic missile threats from rogue nations. During this review, the MDA assessed the NGI program's readiness and maturity to continue into the detailed design phase, confirming that Lockheed Martin's solution continues to meet requirements for the mission.

"I am proud of our team's commitment to innovating with urgency to achieve expectations for this phase of the program," said Sarah Hiza, vice president and general manager of Strategic and Missile Defense at Lockheed Martin. "With this additional confidence in our NGI design through a week-long digital review with our MDA customer, we are on track to deliver the right solution to meet the needs of the nation."

Special probes improve ultrasound imaging in obese patients

Edited image from the publication: scan of the liver of an obese patient. The image quality of the standard ultrasound probe (left) is significantly poorer than that of the high-performance probes (center and left).
Image Credit: Heintz et.al. 2023, Scientific Reports

Ultrasound is used to diagnose many diseases in the abdominal cavity. A new study conducted at the University of Leipzig Medical Center and supported by the Helmholtz Institute for Metabolism, Obesity and Vascular Research (HI-MAG) shows that obesity affects the quality of ultrasound scans of the liver and kidneys. It also shows that the use of high-performance ultrasound probes can improve the anatomical depiction in these patients. The findings have been published in the journal Scientific Reports.

Ultrasound of the abdominal organs is a central diagnostic tool and is recommended as the first-line approach for many medical conditions. Compared with other imaging modalities such as computed tomography (CT) and magnetic resonance imaging (MRI), ultrasound is readily available, avoids unnecessary radiation exposure and can be used in almost every case. However, the accuracy of this method is usually limited in obese individuals because the imaging quality of anatomical structures is impaired. To date, the degree of obesity at which ultrasound diagnostics are no longer sufficiently precise has not been sufficiently researched.

Ultrahigh-sensitivity microprobe optimizes detection of molecular fingerprints

Illustration of a whispering-gallery-mode (WGM) microprobe scanning across a sample substrate to collect 2D mapping of molecular fingerprints of substances.
Illustration Credit: Yang lab

Being a good detective requires top-notch evidence gathering, going where the clues are and recognizing their meaning. The same holds true in the realm of sensing technology, where the quest for the perfect balance between ultrahigh sensitivity and a large detection area has been an ongoing challenge. These properties are crucial for a wide range of applications, from biomedical monitoring and chemical imaging to magnetic sensing and vibration detection.

Optical whispering-gallery-mode microsensors, characterized by their ability to trap light in tiny spherical cavities, have emerged as a promising platform for various sensing applications. However, they have historically struggled to achieve both ultrahigh sensitivity and a substantial detection area simultaneously.

Breaking new ground in the field, researchers working with Lan Yang, the Edwin H. & Florence G. Skinner Professor in the McKelvey School of Engineering at Washington University in St. Louis, have developed a scanning whispering-gallery-mode (WGM) microprobe. This novel device represents a shift in the world of microsensors, offering a remarkable solution to the sensitivity-detection area trade-off conundrum. The findings were published in Light: Science & Applications.

Doubling Down on Known Protein Families

Shedding light on the diversity of microbial communities by looking at protein function within them.
Illustration Credit: Samantha Trieu/Berkeley Lab

Imagine researchers exploring a dark room with a flashlight, only able to clearly identify what falls within that single beam. When it comes to microbial communities, scientists have historically been unable to see beyond the beam – worse, they didn’t even know how big the room is.

A new study published online October 11, 2023 in Nature highlights the vast array of functional diversity of microbes through a novel approach to better understand microbial communities by looking at protein function within them. The work was led by a team of scientists at the U.S. Department of Energy (DOE) Joint Genome Institute (JGI), a DOE Office of Science User Facility located at Lawrence Berkeley National Laboratory (Berkeley Lab), and collaborators across multiple other research centers around the world.

“We’ve more than doubled the number of protein families known up until now, and identified many novel structure predictions,” said lead author on the paper Georgios Pavlopoulos, now a research director at the Biomedical Sciences Research Center Alexander Fleming. “This was a massive analysis of 1.3 billion proteins with massively parallel computations.”

Removal of magnetic spacecraft contamination within extraterrestrial samples easily carried out

PhD student Ji-In Jung, left, and Assistant Professor Sonia Tikoo examine a collection of lunar samples.
 Photo Credit: Harry Gregory

By demonstrating that spaceflight doesn’t adversely affect the magnetism of moon rocks, Stanford researchers underscore the exciting potential of studying the magnetic histories stored in these samples.

For decades, scientists have pondered the mystery of the moon’s ancient magnetism. Based on analyses of lunar samples, its now-deceased magnetic field may have been active for more than 1.5 billion years – give or take a billion years. Scientists believe it was generated like the Earth’s via a dynamo process, whereby the spinning and churning of conductive liquid metal within a rocky planet’s core generates a magnetic field. However, researchers have grappled with how such a small planetary body could have sustained a long-lived magnetic field. Some have even questioned the legitimacy of return samples that point to the existence of an ancient dynamo, suggesting magnetism may have been acquired via exposure to strong magnetic fields onboard spacecraft during the return mission or from plasmas produced by massive impacts on the moon.

Stanford University scientists have now demonstrated that the magnetism in lunar samples is not adversely altered by the spacecraft journey back to Earth or certain laboratory procedures, disproving one of the two major oppositions to the ancient dynamo theory. The findings, published in Geophysical Research Letters Oct. 11, bode well for research stemming from other sample-return missions from space, since any magnetic contamination acquired during flight or on Earth can likely be easily removed.

Superconducting niobium waveguide achieves high-precision communications for B5G/6G networks

Researchers fabricated 20mm length waveguides made of the superconducting metal niobium (right).  It shows improved conductivity compared with normal metal materials such as a gold-plated tellurium copper (middle)  and aluminum alloy (left), and can transmit radio waves that are necessary for B5G/6G communications. 
Photo Credit: Taku Nakajima

A team of researchers has made a breakthrough discovery in the world of Beyond 5G/6G (B5G/6G) signal transmission. Taku Nakajima and Kazuji Suzuki of Nagoya University in Japan, along with their collaborators, created a waveguide made of niobium that speeds up the transition of B5G/6G signals.  

The frequency of data waves has continued to increase as B5G/6G technologies have been introduced. Although the currently used metal transmission lines can handle B5G/6G, research has focused on superconducting metals, such as niobium, that have lower transmission loss and can handle higher frequencies.  

Nakajima and his collaborators evaluated the use of niobium in a waveguide, a three-dimensional transmission line consisting of a metal tube that guides and confines waves along a specific path, minimizing losses due to radiation and absorption. However, working with the metal proved to be difficult as it was susceptible to deformation and damage during fabrication and handling.  

Scorpius images to test nuclear stockpile simulations

Two cathode inductive voltage-adder cells on the electrical test stand are aligned at Sandia National Laboratories. After thousands of tests, each holding 50 kilovolts across the insulating gap, they are ready to be mounted on seven-cell modules.
Photo Credit: Craig Fritz

One thousand feet below the ground, three national defense labs and a remote test site are building Scorpius — a machine as long as a football field — to create images of plutonium as it is compressed with high explosives, creating conditions that exist just prior to a nuclear explosion.

These nanosecond portraits will be compared with visuals of the same events generated by supercomputer codes to check how accurately the computed images replicate the real thing.

“It’s clear we need to know that the stockpile will work if required,” said Jon Custer, Sandia National Laboratories project lead. “Before President Bush’s testing moratorium in 1992, we knew it did since we were physically testing. Now we have computer codes. How well do they predict what really happens? Do we have accurate data we put into the codes? To answer these questions with higher fidelity, we need better experimental tools, and Scorpius is a major new experimental tool.”

The $1.8 billion project, combining the expertise of researchers from Sandia, Los Alamos and Lawrence Livermore national labs with support from the Nevada National Security Site — a test area bigger than the state of Rhode Island — is expected to be up and running by late 2027.

New dog, old tricks: New AI approach yields ‘athletically intelligent’ robotic dog

A doglike robot can navigate unknown obstacles using a simple algorithm that encourages forward progress with minimal effort.

Video Credit: Shanghai Qi Zhi Institute/Stanford University

With a simplified machine learning technique, AI researchers created a real-world “robodog” able to leap, climb, crawl, and squeeze past physical barriers as never before.

Someday, when quakes, fires, and floods strike, the first responders might be packs of robotic rescue dogs rushing in to help stranded souls. These battery-powered quadrupeds would use computer vision to size up obstacles and employ doglike agility skills to get past them.

Toward that noble goal, AI researchers at Stanford University and Shanghai Qi Zhi Institute say they have developed a new vision-based algorithm that helps robodogs scale high objects, leap across gaps, crawl under thresholds, and squeeze through crevices – and then bolt to the next challenge. The algorithm represents the brains of the robodog.

“The autonomy and range of complex skills that our quadruped robot learned is quite impressive,” said Chelsea Finn, assistant professor of computer science and senior author of a new peer-reviewed paper announcing the teams’ approach to the world, which will be presented at the upcoming Conference on Robot Learning. “And we have created it using low-cost, off-the-shelf robots – actually, two different off-the-shelf robots.”

Insect Cyborgs: Towards Precision Movement

Image Credit: ©Dai Owaki

Insect cyborgs may sound like science fiction, but it's a relatively new phenomenon based on using electrical stimuli to control the movement of insects. These hybrid insect computer robots, as they are scientifically called, herald the future of small, high mobile and efficient devices.

Despite significant progress being made, however, further advances are complicated by the vast differences between different insects' nervous and muscle systems.

In a recent study published in the journal eLife, an international research group has studied the relationship between electrical stimulation in stick insects' leg muscles and the resultant torque (the twisting force that makes the leg move).

Pulling carbon dioxide straight from the air

John Hegarty and Ben Shindel with new ions to facilitate carbon capture
Photo Credit: Courtesy of Northwestern University

Even as the world slowly begins to decarbonize industrial processes, achieving lower concentrations of atmospheric carbon requires technologies that remove existing carbon dioxide from the atmosphere — rather than just prevent the creation of it.

Typical carbon capture catches CO2 directly from the source of a carbon-intensive process. Ambient carbon capture, or “direct air capture” (DAC) on the other hand, can take carbon out of typical environmental conditions and serves as one weapon in the battle against climate change, particularly as reliance on fossil fuels begins to decrease and with it, the need for point-of-source carbon capture.

New research from Northwestern University shows a novel approach to capture carbon from ambient environmental conditions that looks at the relationship between water and carbon dioxide in systems to inform the “moisture-swing” technique, which captures CO2 at low humidities and releases it at high humidities. The approach incorporates innovative kinetic methodologies and a diversity of ions, enabling carbon removal from virtually anywhere.

Morphing robots designed at CSU can grip, climb and crawl like insects

Pulling inspiration from the natural world, researchers at Colorado State University have developed a trio of robots that can morph their bodies and legs as needed.

Video Credit: Colorado State University

Pulling inspiration from the natural world, researchers at Colorado State University have developed a trio of robots that can morph their bodies and legs as needed to better crawl, shimmy or swim over difficult terrain.  These new robotic systems are designed to mimic the way biological organisms adapt their shape depending on their life cycle or environment and were developed by a team from the Department of Mechanical Engineering. The work is described in a new paper published in Nature Communications which outlines the three robotic types and their different abilities including gripping, climbing and amphibious travel.

Associate Professor Jianguo Zhao led the research team on campus in the Department of Mechanical Engineering with recent Ph.D. graduate Jiefeng Sun serving as lead author for the paper. Zhao said these robots are made of materials that can become soft or rigid with changes in temperature and are able to move without the need for bulky power systems such as magnetic coils. That makes them more versatile and better equipped to potentially help humans search tight disaster areas for survivors in the future.

‘Impossible’ Millimeter Wave Sensor Has Wide Potential

This prototype millimeter-wave radar sensor developed at UC Davis is capable of measuring extremely small vibrations and movements while being energy-efficient and cheap to produce.
Photo Credit: Omeed Momeni/University of California, Davis

Researchers at the University of California, Davis, have developed a proof-of-concept sensor that may usher in a new era for millimeter wave radars. In fact, they call its design a “mission impossible” made possible.

Millimeter wave radars send fast-moving electromagnetic waves to targets to analyze their movement, position and speed from the waves bounced back. The benefits of millimeter waves are their natural sensitivity to small-scale movements and their ability to focus on and sense data from microscopic objects.

The new sensor uses an innovative millimeter wave radar design to detect vibrations a thousand times smaller, and changes in a target’s position one hundred times smaller, than a strand of human hair, making it better or on par with the world’s most accurate sensors. Yet unlike its peers, this one is the size of a sesame seed, is cheap to produce and features a long battery life.

Professor Omeed Momeni and his lab in the Department of Electrical and Computer Engineering led the effort. It is part of an ongoing project funded by the Foundation for Food & Agriculture Research, or FFAR, to develop a low-cost sensor capable of tracking the water status of individual plants. This new radar is the necessary steppingstone that proves it is possible. The work is published in the September 2023 issue of IEEE Journal of Solid-State Circuits.

Ultrasound may rid groundwater of toxic ‘forever chemicals’

PFAS is notoriously difficult to clean from the environment, but ultrasound may offer a more effective solution compared to past efforts.
Photo Credit: Edward Jenner

New research suggests that ultrasound may have potential in treating a group of harmful chemicals known as PFAS to eliminate them from contaminated groundwater.

Invented nearly a century ago, per- and poly-fluoroalkyl substances, also known as “forever chemicals,” were once widely used to create products such as cookware, waterproof clothing and personal care items. Today, scientists understand that exposure to PFAS can cause a number of human health issues such as birth defects and cancer. But because the bonds inside these chemicals don’t break down easily, they’re notoriously difficult to remove from the environment.

Such difficulties have led researchers at The Ohio State University to study how ultrasonic degradation, a process that uses sound to degrade substances by cleaving apart the molecules that make them up, might work against different types and concentrations of these chemicals.

By conducting experiments on lab-made mixtures containing three differently sized compounds of fluorotelomer sulfonates – PFAS compounds typically found in firefighting foams – their results showed that over a period of three hours, the smaller compounds degraded much faster than the larger ones. This is in contrast to many other PFAS treatment methods in which smaller PFAS are actually more challenging to treat.

Revolutionary X-ray microscope unveils sound waves deep within crystals

Scientists developed a groundbreaking technology that allows them to see sound waves and microscopic defects inside crystals, promising insights that connect ultrafast atomic motion to large-scale macroscopic behaviors.
Photo Credit: Olivier Bonin/SLAC National Accelerator Laboratory

Scientists developed a groundbreaking technology that allows them to see sound waves and microscopic defects inside crystals, promising insights that connect ultrafast atomic motion to large-scale macroscopic behaviors.

Researchers at the Department of Energy’s SLAC National Accelerator Laboratory. Stanford University, and Denmark Technical University have designed a cutting-edge X-ray microscope capable of directly observing sound waves at the tiniest of scales – the lattice level within a crystal. These findings, published last week in Proceedings of the National Academy of Sciences, could change the way scientists study ultrafast changes in materials and the resulting properties.

“The atomic structure of crystalline materials gives rise to their properties and associated ‘use-case’ for an application,” said one of the researchers, Leora Dresselhaus-Marais, an assistant professor at Stanford and SLAC. “The crystalline defects and atomic scale displacements describe why some materials strengthen while others shatter in response to the same force. Blacksmiths and semiconductor manufacturing have perfected our ability to control some types of defects, however, few techniques today can image these dynamics in real-time at the appropriate scales to resolve how those the distortions connect to the bulk properties.”

Tiny CRISPR tool could help shred viruses

Model of a minimal CRISPR-Cas13bt3 molecule generated with a cryo-electron microscope. The RNA to be recognized and cleaved is colored in light blue, while the scissor is formed by the magenta and cyan colored domains. The two loops for controlling the CRISPR-Cas13bt3 are shown in green and red.
 Illustration Credit: Courtesy of the Yang Gao lab/Rice University

Small and precise: These are the ideal characteristics for CRISPR systems, the Nobel-prize winning technology used to edit nucleic acids like RNA and DNA.

Rice University scientists have described in detail the three-dimensional structure of one of the smallest known CRISPR-Cas13 systems used to shred or modify RNA and employed their findings to further engineer the tool to improve its precision. According to a study published in Nature Communications, the molecule works differently than other proteins in the same family.

“There are different types of CRISPR systems, and the one our research was focused on for this study is called CRISPR-Cas13bt3,” said Yang Gao, an assistant professor of biosciences and Cancer Prevention and Research Institute of Texas Scholar who helped lead the study. “The unique thing about it is that it is very small. Usually, these types of molecules contain roughly 1200 amino acids, while this one only has about 700, so that’s already an advantage.”

Clean, sustainable fuels made ‘from thin air’ and plastic waste

Carbon capture from air and its photoelectrochemical conversion into fuel with simultaneous waste plastic conversion into chemicals. 
Photo Credit: Ariffin Mohamad Annuar

Researchers have demonstrated how carbon dioxide can be captured from industrial processes – or even directly from the air – and transformed into clean, sustainable fuels using just the energy from the sun.

The researchers from the University of Cambridge developed a solar-powered reactor that converts captured CO2 and plastic waste into sustainable fuels and other valuable chemical products. In tests, CO2 was converted into syngas, a key building block for sustainable liquid fuels, and plastic bottles were converted into glycolic acid, which is widely used in the cosmetics industry.

Unlike earlier tests of their solar fuels technology however, the team took CO2 from real-world sources – such as industrial exhaust or the air itself. The researchers were able to capture and concentrate the CO2 and convert it into sustainable fuel.

Although improvements are needed before this technology can be used at an industrial scale, the results, reported in the journal Joule, represent another important step toward the production of clean fuels to power the economy, without the need for environmentally destructive oil and gas extraction.

GE Aerospace runs one of the world’s largest supercomputer simulations to test revolutionary new open fan engine architecture

CFM’s RISE open fan engine architecture.
Image Credit: GE Aerospace

To support the development of a revolutionary new open fan engine architecture for the future of flight, GE Aerospace has run simulations using the world’s fastest supercomputer capable of crunching data in excess of exascale speed, or more than a quintillion calculations per second.

To model engine performance and noise levels, GE Aerospace created software capable of operating on Frontier, a recently commissioned supercomputer at the U.S. Department of Energy’s (DOE) Oak Ridge National Laboratory with processing power of about 37,000 GPUs. For comparison, Frontier’s processing speed is so powerful, it would take every person on Earth combined more than four years to do what the supercomputer can in one second.  

By coupling GE Aerospace’s computational fluid dynamics software with Frontier, GE was able to simulate air movement of a full-scale open fan design with incredible detail.

“Developing game-changing new aircraft engines requires game-changing technical capabilities. With supercomputing, GE Aerospace engineers are redefining the future of flight and solving problems that would have previously been impossible,” said Mohamed Ali, vice president and general manager of engineering for GE Aerospace.

Researchers created a new and improved way to view the mechanics of life

RESORT. A diagram to show the basic overview of the system. Firstly, the sample is labeled with the photoswitchable Raman probe. It’s then irradiated with two-color infrared laser pulses, ultraviolet light, and a special donut-shaped beam of visible light to constrain the area where Raman scattering can occur. As a result, the probe can be detected at a very precise point for high spatial resolution images.
Illustration Credit: ©2023 Ozeki et al.
(CC BY 2.0)

There are various ways to image biological samples on a microscopic level, and each has its own pros and cons. For the first time, a team of researchers, including those from the University of Tokyo, has combined aspects from two of the leading imaging techniques to craft a new method of imaging and analyzing biological samples. Its concept, known as RESORT, paves the way to observe living systems in unprecedented detail.

For as long as humanity has been able to manipulate glass, we have used optical devices to peer at the microscopic world in ever increasing detail. The more we can see, the more we can understand, hence the pressure to improve upon tools we use to explore the world around, and inside, us. Contemporary microscopic imaging techniques go far beyond what traditional microscopes can offer. Two leading technologies are super-resolution fluorescence imaging, which offers good spatial resolution, and vibrational imaging, which compromises spatial resolution but can use a broad range of colors to help label many kinds of constituents in cells.

Navigating underground with cosmic-ray muons

Navigating inside with muons. The red line in this image represents the path the “navigatee” walked, while the white line with dots shows the path recorded by MuWNS.
Illustration Credit: ©2023 Hiroyuki K.M. Tanaka

Superfast, subatomic-sized particles called muons have been used to wirelessly navigate underground in a reportedly world first. By using muon-detecting ground stations synchronized with an underground muon-detecting receiver, researchers at the University of Tokyo were able to calculate the receiver’s position in the basement of a six-story building. As GPS cannot penetrate rock or water, this new technology could be used in future search and rescue efforts, to monitor undersea volcanoes, and guide autonomous vehicles underground and underwater.

GPS, the global positioning system, is a well-established navigation tool and offers an extensive list of positive applications, from safer air travel to real-time location mapping. However, it has some limitations. GPS signals are weaker at higher latitudes and can be jammed or spoofed (where a counterfeit signal replaces an authentic one). Signals can also be reflected off surfaces like walls, interfered with by trees, and can’t pass through buildings, rock or water.

Energy Harvesting Via Vibrations: Researchers develop highly durable and efficient device

The principle, structural design, and application of carbon fiber-reinforced polymer-enhanced piezoelectric nanocomposite materials.
Illustration Credit: ©Tohoku University

An international research group has engineered a new energy-generating device by combining piezoelectric composites with carbon fiber-reinforced polymer (CFRP), a commonly used material that is both light and strong. The new device transforms vibrations from the surrounding environment into electricity, providing an efficient and reliable means for self-powered sensors.

Details of the group's research were published in the journal Nano Energy.

Energy harvesting involves converting energy from the environment into usable electrical energy and is something crucial for ensuring a sustainable future.

"Everyday items, from fridges to street lamps, are connected to the internet as part of the Internet of Things (IoT), and many of them are equipped with sensors that collect data," says Fumio Narita, co-author of the study and professor at Tohoku University's Graduate School of Environmental Studies. "But these IoT devices need power to function, which is challenging if they are in remote places, or if there are lots of them."