Floating solar panels show promise, but environmental impacts vary by location

The Canoe Brook Floating Solar Photovoltaic (FPV) project, the largest in the United States at the time of completion at 8.9 MW, is located on a water storage reservoir is New Jersey.
Photo Credit Prateek Joshi / NREL

Floating solar panels are emerging as a promising clean energy solution with environmental benefits, but a new study finds those effects vary significantly depending on where the systems are deployed.

Researchers from Oregon State University and the U.S. Geological Survey modeled the impact of floating solar photovoltaic systems on 11 reservoirs across six states. Their simulations showed that the systems consistently cooled surface waters and altered water temperatures at different layers within the reservoirs. However, the panels also introduced increased variability in habitat suitability for aquatic species.

“Different reservoirs are going to respond differently based on factors like depth, circulation dynamics and the fish species that are important for management,” said Evan Bredeweg, lead author of the study and a former postdoctoral scholar at Oregon State. “There’s no one-size-fits-all formula for designing these systems. It’s ecology - it’s messy.”

A new way to trigger responses in the body

Photo Credit: Courtesy of University of Tokyo

Researchers at the University of Tokyo developed an experimental method to induce a strong physiological response linked to psychological pressure by making participants aim for a streak of success in a task. Their findings suggest this approach reproduces pressurelike conditions in a laboratory setting more effectively than traditional methods, affording easier access to the study of this state. That in turn could open up research into how pressure influences human performance in physical and intellectual tasks.

Whether in an exam hall or on the field, to “crack” under pressure is a common trope. But what’s the reality behind this idea? It’s easy to assume that with greater pressure comes greater chance of losing your composure. To know, then, how to overcome this could yield greater performance benefits. But the path to study such ideas is far from simple. Being rigorous in the field of psychology is extremely difficult, as there are limitless factors that can impact different people in different ways. Previous experimental methods have been limited in that they failed to induce strong physiological arousal.

SwRI turbocharges its hydrogen-fueled internal combustion engine

SwRI has a multidisciplinary team dedicated to Hydrogen Energy Research initiatives to deploy decarbonization technologies across a broad spectrum of industries. In 2022, SwRI began modifying a heavy-duty natural gas-fueled engine to run on 100% hydrogen fuel, successfully demonstrated in 2024. SwRI continues to research, design and innovate on H2-ICE technology. 
Photo Credit: Southwest Research Institute

Southwest Research Institute (SwRI) has upgraded its hydrogen-powered heavy-duty internal combustion engine (H2-ICE) with a state-of-the-art turbocharger. The upgrades have significantly improved performance across the board, making the engine competitive with current long-haul diesel engines focused on fuel economy while maintaining near-zero tailpipe emissions.

In 2023, SwRI converted a traditional natural gas-fueled internal combustion engine to run solely on hydrogen fuel with minimal modifications. It was integrated into a Class-8 truck as part of the Institute’s H2-ICE project to demonstrate a cost-efficient hydrogen-fueled engine as an option for zero-tailpipe carbon dioxide heavy-duty transportation.

Entomology: In-Depth Description

Photo Credit: Lidia Stawinska

Entomology is the scientific study of insects, a branch of zoology. Its primary goals are to understand the biology, behavior, physiology, ecology, evolution, and classification of insects, as well as their interactions with humans, other organisms, and the environment.

A new angle of study for unveiling black hole secrets

The balloon-borne telescope XL-Calibur was launched on a six-day flight from the Swedish Space Corporation’s Esrange Space Center in July 2024. During that flight, the telescope took measurements from the black hole Cygnus X-1, located about 7,000 light-years away. WashU researchers will use those results to improve computer models for simulating and uncovering further mysteries of black holes.
Photo Credit: NASA/SSC

An international collaboration of physicists including researchers at Washington University in St. Louis has made measurements to better understand how matter falls into black holes and how enormous amounts of energy and light are released in the process.

The scientists pointed a balloon-borne telescope called XL-Calibur at a black hole, Cygnus X-1, located about 7,000 light-years from Earth. “The observations we made will be used by scientists to test increasingly realistic, state-of-the-art computer simulations of physical processes close to the black hole,” said Henric Krawczynski, the Wilfred R. and Ann Lee Konneker Distinguished Professor in Physics and a fellow at WashU’s McDonnell Center for the Space Sciences.

Disrupting bacterial "chatter" to improve human health

Computer-rendered split image of bacteria on a tooth surface. When microbial communication is “on”, disease-associated species grow (left). Disrupting this communication (right) promotes health-associated bacteria.
Image Credit: University of Minnesota

Scientific Frontline: Extended "At a Glance" Summary: Disrupting Bacterial "Chatter" (Quorum Sensing)

The Core Concept: Bacteria communicate and coordinate behavior through a continuous chemical signaling process known as quorum sensing. By strategically disrupting these chemical messages, scientists can manipulate bacterial communities to prevent illness and promote a healthy microbiome without eradicating beneficial species.

Key Distinction/Mechanism: Unlike traditional antibiotics and disinfectants that indiscriminately kill both good and bad bacteria—a process that fuels antibiotic resistance—this approach targets the communication network itself. By using specialized enzymes called lactonases, researchers can block specific signal molecules known as N-acyl homoserine lactones (AHLs). This effectively cuts off the "chatter" that allows disease-causing bacteria to thrive, naturally shifting the ecosystem back to a health-associated state.

Major Frameworks/Components:

• Quorum Sensing: The biological mechanism of communication where bacteria release and detect chemical signals to regulate collective behaviors.
• N-acyl homoserine lactones (AHLs): Specific molecular messengers produced by bacteria in aerobic (oxygen-rich) environments, which can travel to and influence bacteria in anaerobic (oxygen-deprived) zones below the gumline.
• Lactonases: The specialized enzymes deployed to neutralize AHL signals, effectively silencing the communication of harmful bacteria.
• Microbial Succession: The progression of plaque development, starting with harmless "pioneer species" (like Streptococcus) and culminating in disease-associated "late colonizers" (like Porphyromonas gingivalis).
• Oxygen Availability Dynamics: The role of quorum sensing varies drastically based on oxygen; blocking AHLs above the gumline promotes healthy bacteria, while signaling below the gumline encourages the growth of disease-causing species.

Wastewater from most countries favors non-resistant bacteria

Joakim Larsson, Professor at the Institute of Biomedicine, Sahlgrenska Academy at the University of Gothenburg, and director of CARe, Centre for Antibiotic Resistance Research.
Photo Credit: Johan Wingborg

A global study led by researchers at the Centre for Antibiotic Resistance Research (CARe) in Gothenburg, Sweden shows that municipal wastewater is not always the breeding ground for antibiotic resistance it is often thought to be. By testing wastewater from 47 countries, the team found that while some samples could select for resistant E. coli, the majority instead selected against resistance. These insights reshape our understanding of when and where resistance is likely to evolve and spread. 

Municipal wastewater contains a large range of excreted antibiotics and has therefore long been suspected to be a spawning ground for antibiotic-resistant bacteria. Now, a study published in Nature Communications led by a team from the University of Gothenburg provides a more nuanced picture. 

Two-step flash Joule heating method recovers lithium‑ion battery materials quickly and cleanly

(From left) Shichen Xu, James Tour, Alex Lathem, Karla Silva and Ralph Abdel Nour.
Photo Credit: Jared Jones/Rice University

A research team at Rice University led by James Tour has developed a two-step flash Joule heating-chlorination and oxidation (FJH-ClO) process that rapidly separates lithium and transition metals from spent lithium-ion batteries. The method provides an acid-free, energy-saving alternative to conventional recycling techniques, a breakthrough that aligns with the surging global demand for batteries used in electric vehicles and portable electronics.

Published in Advanced Materials, this research could transform the recovery of critical battery materials. Traditional recycling methods are often energy intensive, generate wastewater and frequently require harsh chemicals. In contrast, the FJH-ClO process achieves high yields and purity of lithium, cobalt and graphite while reducing energy consumption, chemical usage and costs.

“We designed the FJH-ClO process to challenge the notion that battery recycling must rely on acid leaching,” said Tour, the T.T. and W.F. Chao Professor of Chemistry and professor of materials science and nanoengineering. “FJH-ClO is a fast, precise way to extract valuable materials without damaging them or harming the environment.”

Oral insulin delayed onset of type 1 diabetes in some children with increased risk of the disease

Half of the participants received daily treatment with oral insulin, and the other half received placebo.
 Photo Credit: Kennet Ruona

An international team of researchers has investigated whether oral insulin can prevent early signs of type 1 diabetes and clinical diagnosis in children with an increased risk of developing the disease. Although treatment with oral insulin could not prevent development of diabetes-related autoantibodies, oral insulin delayed the rate of disease progression in children who developed such autoantibodies. The results from the POInT study are now published in The Lancet. 

The POInT study has investigated whether treatment with oral insulin can prevent diabetes-related autoantibodies and type 1 diabetes in children with an increased genetic risk of developing the disease. These autoantibodies are used as biomarkers for type 1 diabetes, and the presence of two or more autoantibodies is called early-stage type 1 diabetes. The international study includes 1,050 children from Sweden, Germany, Poland, Belgium and the United Kingdom. Half of the participants received daily treatment with oral insulin, and the other half received placebo during their first three years of life. In type 1 diabetes, the body’s immune system attacks the insulin-producing beta cells in the pancreas and destroys them. 

Engineering: In-Depth Description

Photo Credit: ThisisEngineering

Engineering is the application of scientific principles, mathematical knowledge, economic considerations, and practical experience to invent, design, build, maintain, and improve structures, machines, tools, systems, components, materials, and processes. The primary goal of engineering is to solve practical human problems safely, efficiently, and effectively.

A Microbial Blueprint for Climate-Smart Cows

Matthias Hess, with the UC Davis Department of Animal Science, and researchers at UC Berkeley, have identified which microbes in a cow's gut could help reduce methane. It brings them a step closer to engineering gut microbes to create more climate-friendly cows.
Photo Credit: Gregory Urquiaga / UC Davis

Each year, a single cow can belch about 200 pounds of methane. The powerful greenhouse gas is 27 times more potent at trapping heat in the atmosphere than carbon dioxide. For decades, scientists and farmers have tried to find ways to reduce methane without stunting the animal’s growth or productivity. 

Recent research at University of California, Davis, has shown that feeding cows red seaweed can dramatically cut the amount of methane that is produced and released into the environment. Until now, however, scientists did not fully understand how red seaweed changes the interactions among the thousands of microbes in the cow’s gut, or rumen. 

Researchers Unveil First-Ever Defense Against Cryptanalytic Attacks on AI

Image Credit: Scientific Frontline

Security researchers have developed the first functional defense mechanism capable of protecting against “cryptanalytic” attacks used to “steal” the model parameters that define how an AI system works.

“AI systems are valuable intellectual property, and cryptanalytic parameter extraction attacks are the most efficient, effective, and accurate way to ‘steal’ that intellectual property,” says Ashley Kurian, first author of a paper on the work and a Ph.D. student at North Carolina State University. “Until now, there has been no way to defend against those attacks. Our technique effectively protects against these attacks.”

“Cryptanalytic attacks are already happening, and they’re becoming more frequent and more efficient,” says Aydin Aysu, corresponding author of the paper and an associate professor of electrical and computer engineering at NC State. “We need to implement defense mechanisms now, because implementing them after an AI model’s parameters have been extracted is too late.”

A sparkling ‘Diamond Ring’ in space: Astronomers in Cologne unravel the mystery of a cosmic ring

Stars Brewing in Cygnus X
Image Credit: NASA/JPL-Caltech/Harvard-Smithsonian CfA

The structure of gas and dust resembles a glowing diamond ring. Computer simulations and observations made on board the 'flying observatory' SOFIA are now able to explain the special shape. 

An international team led by researchers from the University of Cologne has solved the mystery of an extraordinary phenomenon known as the ‘Diamond Ring’ in the star-forming region Cygnus X, a huge, ring-shaped structure made of gas and dust that resembles a glowing diamond ring. In similar structures, the formations are not flat but spherical in shape. How this special shape came about was previously unknown. The results have been published under the title ‘The Diamond Ring in Cygnus X: an advanced stage of an expanding bubble of ionized carbon’ in the journal Astronomy & Astrophysics. 

The ring has a diameter of around 20 light years and shines strongly infrared light. It is the relic of a former cosmic bubble that was once formed by the radiation and winds of a massive star. In contrast to other similar objects, the ‘Diamond Ring’ does not have a rapidly expanding spherical shell, but only a slowly expanding ring. 

TU Dresden Develops Laser Drill to Explore Icy Moons

Researchers from TU Dresden during field tests of the laser ice drill on a glacier in Austria
Photo Credit: Technische Universitat Dresden

Researchers at the Institute of Aerospace Engineering at TU Dresden have developed a laser-based ice drilling system that could help to penetrate the kilometer-thick layers of ice on celestial bodies such as Jupiter's moon Europa or Saturn's Enceladus in the future. In this way, underground oceans and possible traces of past life could be investigated in a targeted manner. Initial laboratory and field tests on glaciers in the Alps and the Arctic have shown that snow and ice density can be reliably measured.

Molecules assem­bled by hand

Weakly bound KCs molecules are transferred into what is known as their “absolute ground state”.
Image Credit: University of Innsbruck

Researchers from Hanns-Christoph Nägerl's group have produced the world’s first ultracold KCs molecules in their absolute ground state. Starting by mixing clouds of potassium and caesium atoms cooled almost to absolute zero temperature, they were able to use a combination of magnetic fields and laser beams to associate pairs of freely moving atoms into chemically stable molecules. 

As many of us remember from chemistry classes, molecules can only be produced in chemical reactions, which always occur at unpredictable, random times. We may also remember that higher temperatures make reactions faster, and sufficiently low temperatures may stop reactions from taking place altogether. These statements do not apply if chemistry is conducted by physicists. In the last 20 years, several different types of molecules have been produced in gaseous mixtures at temperatures close to absolute zero, using methods that narrow the exact time at which the molecules are made to a few microseconds. Until recently, KCs remained a gaping hole in the table of possible element combinations that have already been turned into molecules in this way.