Cyber vulnerability in networks used by spacecraft, aircraft and energy generation systems

A new attack discovered by the University of Michigan and NASA exploits a trusted network technology to create unexpected and potentially catastrophic behavior

A major vulnerability in networking technology widely used in critical infrastructures such as spacecraft, aircraft, energy generation systems and industrial control systems was exposed by researchers at the University of Michigan and NASA.

It goes after a network protocol and hardware system called time-triggered ethernet, or TTE, which greatly reduces costs in high-risk settings by allowing mission-critical devices (like flight controls and life support systems) and less important devices (like passenger WiFi or data collection) to coexist on the same network hardware. This blend of devices on a single network arose as part of a push by many industries to reduce network costs and boost efficiency.

That coexistence has been considered safe for more than a decade, predicated on a design that prevented the two types of network traffic from interfering with one another. The team’s attack, called PCspooF, was the first of its kind to break this isolation.

In one compelling demonstration, the team used real NASA hardware to recreate a planned Asteroid Redirection Test. The experimental setup controlled a simulated crewed capsule, specifically at the point in the mission when the capsule prepared to dock with a robotic spacecraft.

Birds of a feather flock together?

Maria Castaño uses a spectrophotometer to analyze tanager feathers.
Photo Credit: University of Rochester | J. Adam Fenster

A biology PhD student analyzes tanager bird feathers to explore how species evolve over time.

Maria Castaño, a third-year PhD student at the University of Rochester in the lab of Al Uy, a professor of biology, studies populations of birds to understand the processes that lead to the creation of new species.

Castaño collects and analyzes DNA sequences and feathers of tanagers from her native Colombia in South America. Her research focuses on two different subspecies of tanagers, which have different colored feathers on their rump areas: one subspecies lives in the lowlands of Colombia and has yellow rump feathers, while another subspecies lives in the mountains and has red rump feathers.

Boeing Demonstrates New Autonomous Anti-Jam Capabilities for U.S. Space Force Satellite Communications Program

Boeing engineers recently demonstrated its space-based smart antenna technology, which detects enemy jammers and autonomously reshapes a satellite’s beams to suppress hostile jammers while maintaining communications with the friendly-force PTS terminals. Boeing’s system brings communication to the warfighter at closer range to the enemy.
Photo Credit: Boeing

Boeing engineers recently demonstrated a new, autonomous technology that can successfully prevent jamming attempts on U.S. Department of Defense satellite communications (SATCOM). The test was conducted on the U.S. Space Force’s Protected Tactical SATCOM Prototype (PTS-P), showing how this technology can provide secure communication in contested environments.

“Maintaining communication with our deployed forces during hostility gives us a tactical edge on the battlefield,” said Justin Bruner, PTS-P Program Manager at the U.S. Space Force. “Our adversaries are always attempting to deny our ability to communicate. On-board, autonomous, real-time nulling of jammers greatly enhances our resiliency, ensuring the United States and our allies can provide our warfighters with secure, reliable communications in a contested environment. Boeing has made significant strides in the development and execution of a nulling algorithm with flight-like firmware, demonstrating agile anti-jam capability. PTS-P and all of our Protected Anti-Jam Tactical SATCOM (PATS) programs are critical to this effort.”

New discoveries made about a promising solar cell material, thanks to new microscope

Visualization of the microscope tip exposing material to terahertz light. The colors on the material represent the light-scattering data, and the red and blue lines represent the terahertz waves.
Illustration Credit: Ames National Laboratory

A team of scientists from the Department of Energy’s Ames National Laboratory developed a new characterization tool that allowed them to gain unique insight into a possible alternative material for solar cells. Under the leadership of Jigang Wang, senior scientist from Ames Lab, the team developed a microscope that uses terahertz waves to collect data on material samples. The team then used their microscope to explore Methylammonium Lead Iodide (MAPbI3) perovskite, a material that could potentially replace silicon in solar cells.

Richard Kim, a scientist from Ames Lab, explained the two features that make the new scanning probe microscope unique. First, the microscope uses the terahertz range of electromagnetic frequencies to collect data on materials. This range is far below the visible light spectrum, falling between the infrared and microwave frequencies. Secondly, the terahertz light is shined through a sharp metallic tip that enhances the microscope’s capabilities toward nanometer length scales.

“Normally if you have a light wave, you cannot see things smaller than the wavelength of the light you're using. And for this terahertz light, the wavelength is about a millimeter, so it’s quite large,” explained Kim. “But here we used this sharp metallic tip with an apex that is sharpened to a 20-nanometer radius curvature, and this acts as our antenna to see things smaller than the wavelength that we were using.”

New critical period of sex determination in sea turtles identified

Sea turtles’ sex is determined based on the environment, which makes them especially vulnerable to climate change. An increase in incubation temperatures could jeopardize the production of both sexes.
 Photo credit: Jay Paredes

Unlike humans, turtles, lizards and other reptiles – such as crocodiles – do not have sex chromosomes. Their sex is determined based on the environment, which makes them especially vulnerable to climate change. An increase in incubation temperatures could jeopardize the production of both sexes.

Gauging primary sex ratios in these species is critical because it assesses their vulnerability under both current and future climate change constraints. While there has been great progress in sex ratio prediction, studies have been hampered due to a lack of accurate and representative regional and population sex ratio estimates. As a result, primary sex ratios calculations could be skewed.

Researchers from Florida Atlantic University, in collaboration with the Université Paris-Saclay in France, have demonstrated that the timing of key developmental process driven by temperature is vital when it comes to identifying when sex is determined for sea turtle embryos. They also are the first to compare the output of the most widely used sex ratio prediction methods to actual sex ratios from natural clutches in sea turtles.

They have developed a new way to integrate the effect of thermal fluctuations on embryonic sex determination and predict sex ratios with much better accuracy than prior models. This method measures the strength of masculinization or feminization of temperatures using novel parameters that have uncovered how temperature-sensitive sex determination works.

Tiny molecules in breast milk may protect infants from developing allergies

A new study by Penn State College of Medicine researchers found that small molecules found in most humans’ breast milk may reduce the likelihood of infants developing allergic conditions like atopic dermatitis and food allergies.
Photo Credit: Gustavo Fring

Breastfed babies are believed to suffer fewer allergic conditions, like eczema and food allergies, than formula-fed babies; yet the reason has not been well understood. Now, a new study by Penn State College of Medicine finds that small molecules found in most humans’ breast milk may reduce the likelihood of infants developing allergic conditions like atopic dermatitis and food allergies. The researchers said the discovery could lead to strategies for mothers — such as encouragement and support for breastfeeding or dietary and exercise interventions — to help lower the odds of their babies developing allergies.

Atopic conditions, like food allergies, asthma and a skin condition called atopic dermatitis occur in approximately one-third of children as a result of inappropriate activation of the immune system to environmental exposures.

“Infants who breastfeed beyond three months may have a lower risk for these conditions, but we don’t fully understand the biology behind this,” said Dr. Steven Hicks, associate professor of pediatrics and pediatrician at Penn State Health Children’s Hospital.

Understanding a cerium quirk could help advance grid-scale energy storage

When the cerium atom is short three electrons, it is surrounded by water molecules. But when it gives up a fourth electron, some water molecules shift out of the way to let in sulfates. This dance costs energy, but understanding that energy loss paves the way for more efficient cerium batteries.
Image Credit: Dylan Herrera, Goldsmith Lab, University of Michigan

It turns out cerium flow batteries lose voltage when electrolyte molecules siphon off energy to form different complexes around the metal

An explanation for why flow batteries using the metal cerium in a sulfuric acid electrolyte fall short on voltage, discovered through a study led by the University of Michigan, could pave the way for better battery chemistry.

Flow batteries are one of the methods under consideration for storing intermittent sources of renewable electricity, such as solar and wind power. They can bank large quantities of energy by keeping the chemical potential in liquid form, with two electrolytes that flow through porous electrodes to charge and discharge. The metal cerium could store energy at a relatively high voltage, meaning more energy per metal ion, and at low cost.

One of the challenges with cerium is figuring out how to make electric charges transfer to and from the electrode efficiently. On its way through the positive electrode, cerium either picks up or drops off an electron, depending on whether the battery is charging or discharging.

However, the cerium in a sulfuric acid electrolyte doesn’t pick up and drop off the electron as quickly as expected, meaning energy is wasted. It turned out that the water molecules and sulfate molecules were doing a complicated dance around the cerium, and that’s how the energy was lost.

Autonomous Crawling Soft ‘Ringbots’ Can Navigate Narrow Gaps

Researchers at North Carolina State University have created a ring-shaped soft robot capable of crawling across surfaces when exposed to elevated temperatures or infrared light. The researchers have demonstrated that these “ringbots” are capable of pulling a small payload across the surface – in ambient air or under water, as well as passing through a gap that is narrower than its ring size.

The ringbots are made of liquid crystal elastomers in the shape of looped ribbon, resembling a bracelet. When you place the ringbot on a surface that is at least 55 degrees Celsius (131 degrees Fahrenheit), which is hotter than the ambient air, the portion of the ribbon touching the surface contracts, while the portion of the ribbon exposed to the air does not. This induces a rolling motion in the ribbon. 

Similarly, when researchers shine infrared light on the ringbot, the portion of the ribbon exposed to the light contracts, while the portion shielded from the light does not. This also induces a rolling motion in the ribbon.

In practical terms, this means that the crawling ringbot moves from the bottom up when placed on a hot surface. But when exposed to infrared light, the movement begins from the top down.

One of the things that drives this continuous motion is the fact that the ringbots are bistable, meaning that there are two shapes when it is at rest. If the ribbon begins to twist, it will either snap back to its original shape, or snap forward into the other bistable state.

UiB scientists discover 80 000-year-old bone tools

80 000 Year Bone Tools: From left to right: experimental debarking in Africa, the bone tool tip after use, Francesco d'Errico taking replicas in the field of an experimental bone tool.
Resized Image using AI by SFLORG
Photo Credit: UiB, SapienCE

Until the beginning of this century, the production of fully worked bone tools was considered an innovation introduced in Europe around 40,000 years ago by modern humans. Research carried out over the last two decades has led to the discovery of bone tools in several regions of Africa, some of which could date back 100,000 years. But these early bone tools are rare and non-standardized in shape.

Key cultural innovations

The discovery of 23 bone tools from the Sibudu rock shelter, Kwa Zulu-Natal, South Africa, all with a flattened ogival-shaped end, found in archaeological layers dated to between 80 000 and 60 000 years ago, changes the picture.

“Our new study documents the technology and function of the earliest fully shaped bone tools from this region. The discovery of these tools contributes to a better understanding of when and how these innovations arose, and what they were used for,” Francesco d’Errico says. He is the lead author on the paper just published in Scientific Reports.

d’Errico is part of the SapienCE team at the University of Bergen. The SapienCE Centre of Excellence, funded by Norwegian Research Council, consists of an interdisciplinary team of world leading scientists. The aim for SapienCE is to improve our understanding of how and when Homo sapiens evolved into who we are today.

Sandia studies vulnerabilities of electric vehicle charging infrastructure

Kaedi Sanchez plugs in her car at a City of Albuquerque electric vehicle charger before heading to work. Sandia National Laboratories researchers have been studying the vulnerabilities of electric vehicle charging infrastructure, including public chargers, to better inform policymakers.
Photo Credit: Craig Fritz

With electric vehicles becoming more common, the risks and hazards of a cyber-attack on electric vehicle charging equipment and systems also increases. Jay Johnson, an electrical engineer at Sandia National Laboratories, has been studying the varied vulnerabilities of electric vehicle charging infrastructure for the past four years.

Johnson and his team recently published a summary of known electric vehicle charger vulnerabilities in the scientific journal Energies.

“By conducting this survey of electric vehicle charger vulnerabilities, we can prioritize recommendations to policymakers and notify them of what security improvements are needed by the industry,” Johnson said. “The Bipartisan Infrastructure Law allocates $7.5 billion to electric vehicle charging infrastructure. As a part of this funding, the federal government is requiring states to implement physical and cybersecurity strategies. We hope our review will help prioritize hardening requirements established by the states. Our work will also help the federal government standardize best practices and mandate minimum security levels for electric vehicle chargers in the future.”