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Category: sustainability

Exposure to common air pollutants alters adolescent brain development, study finds

Physician-scientists at Oregon Health & Science University warn that exposure to air pollution may have serious implications for a child’s developing brain.

In a recent study published in the journal Environmental Research, researchers in OHSU’s Developmental Brain Imaging Lab found that air pollution is associated with structural changes in the adolescent brain, specifically in the frontal and temporal regions —the areas responsible for executive function, language, mood regulation and socioemotional processing.

Air pollution causes harmful contaminants, such as particulate matter, nitrogen dioxide and ozone, to circulate in the environment. It has been exacerbated over the past two centuries by industrialization, vehicle emissions, and, more recently, wildfires.

Vapor-deposition method delivers unprecedented durability in perovskite–silicon tandem solar cells

NUS researchers have developed a vapor-deposition method that dramatically improves the long-term and high-temperature stability of perovskite-silicon (Si) tandem solar cells. The findings were published in Science.

This is the first time vapor deposition has been successfully applied to industrial micrometer-textured silicon wafers, the actual wafer structure used in commercial solar cell manufacturing, marking a major milestone for translating laboratory-scale tandem solar cells into real-world products.

The new method enables conformal, high-quality perovskite growth on industrial micrometer-scale textured silicon wafers, a critical requirement for mass production, and delivers more than 30% power-conversion efficiency with operational stability far exceeding 2,000 hours, including T₉₀ lifetimes —the time taken for performance to drop to 90% of initial output—of over 1,400 hours at 85°C under 1-sun illumination, a standard benchmark in solar energy representing a light intensity of 1,000 watts per square meter.

Ultra-low power, fully biodegradable artificial synapse offers record-breaking memory

In Nature Communications, a research team affiliated with UNIST present a fully biodegradable, robust, and energy-efficient artificial synapse that holds great promise for sustainable neuromorphic technologies. Made entirely from eco-friendly materials sourced from nature—such as shells, beans, and plant fibers—this innovation could help address the growing problems of electronic waste and high energy use.

Traditional artificial synapses often struggle with high power consumption and limited lifespan. Led by Professor Hyunhyub Ko from the School of Energy and Chemical Engineering, the team aimed to address these issues by designing a device that mimics the brain’s synapses while being environmentally friendly.

Molecules as switches for sustainable light-driven technologies

Metal nanostructures can concentrate light so strongly that they can trigger chemical reactions. The key players in this process are plasmons—collective oscillations of free electrons in the metal that confine energy to extremely small volumes. A new study published in Science Advances now shows how crucial adsorbed molecules are in determining how quickly these plasmons lose their energy.

The team led by LMU nanophysicists Dr. Andrei Stefancu and Prof. Emiliano Cortés identified two fundamentally different mechanisms of so-called chemical interface damping (CID), the plasmon damping caused by adsorbed molecules. Which mechanism dominates depends on how the electronic states of the molecule align with those of the metal surface, gold in this case—and this alignment is even reflected in the material’s electrical resistance.

Hybrid excitons: Combining the best of both worlds

Faster, more efficient, and more versatile—these are the expectations for the technology that will produce our energy and handle information in the future. But how can these expectations be met? A major breakthrough in physics has now been made by an international team of researchers from the Universities of Göttingen, Marburg, the Berlin Humboldt in Germany, and Graz in Austria.

The scientists combined two highly promising types of material—organic semiconductors and two-dimensional semiconductors—and studied their combined response to light using photoelectron spectroscopy and many-body perturbation theory.

This enabled them to observe and describe fundamental microscopic processes, such as energy transfer, at the 2D-organic interface with ultrafast time resolution, meaning one quadrillionth of a second. The combination of these properties holds promise for developing new technology such as the next generation of solar cells. The results are published in Nature Physics.

Batteries lose charge when they ‘breathe’: Understanding deterioration is a step toward longer-lasting batteries

Researchers have identified a key reason why the batteries used to power everything from smartphones to electric vehicles deteriorate over time, a critical step toward building faster, more reliable and longer-lasting batteries.

The research team from The University of Texas at Austin, Northeastern University, Stanford University and Argonne National Laboratory found that every cycle of charge and discharge causes batteries to expand and contract, similar to human breathing. This action causes battery components to warp just a tiny amount, putting strain on the battery and weakening it over time. This phenomenon, known as chemomechanical degradation, leads to reduced performance and lifespan.

The findings are published in the journal Science.

Putting the squeeze on dendrites: New strategy addresses persistent problem in next-generation solid-state batteries

New research by Brown University engineers identifies a simple strategy for combating a major stumbling block in the development of next-generation solid-state lithium batteries.

Solid-state batteries are considered the next frontier in energy storage, particularly for electric vehicles. Compared to current liquid electrolyte batteries, solid-state batteries have the potential for faster charging, longer range and safer operation due to decreased flammability. But there’s been a consistent problem holding back their commercialization: lithium dendrites.

Dendrites are filaments of lithium metal that can grow inside a battery’s electrolyte (the part of the battery that separates the anode from the cathode) during charging at high current. When they grow across the electrolyte, dendrites cause circuits between the battery’s anode and cathode, which destroy the battery. So while solid electrolytes can—in theory—enable faster charging than liquid electrolytes, the dendrite problem is one of the primary limitations that has to date prevented them from reaching that potential.

Engineers develop real-time membrane imaging for sustainable water filtration

CU Boulder researchers have introduced a solution to improving the performance of large-scale desalination plants: stimulated Raman scattering (SRS).

Published in the journal Environmental Science & Technology, the laser-based imaging method allows researchers to observe in real-time membrane fouling, a process where unwanted materials such as salts, minerals and microorganisms accumulate on filtration membranes.

Worldwide, 55% of people experience water scarcity at least one month a year, and that number is expected to climb to 66% by the end of the century.

Climate whiplash by 2064: Study projects extreme swings in rainfall and drought for Asia

A climate study led by The Hong Kong University of Science and Technology (HKUST), in collaboration with an international research team, reveals that under a high-emission scenario, the Northern Hemisphere summer monsoons region will undergo extreme weather events starting in 2064. Asia and broader tropical regions will face frequent “subseasonal whiplash” events, characterized by extreme downpours and dry spells alternating every 30 to 90 days which trigger climate disruptions with catastrophic impacts on food production, water management, and clean energy systems.

Published in Science Advances under the title “Increased Global Subseasonal Whiplash by Future BSISO Behavior,” the research was co-led by Prof. Lu Mengqian, Director of the Otto Poon Center for Climate Resilience and Sustainability and Associate Professor of the Department of Civil and Environmental at HKUST and Dr. Cheng Tat-Fan, a postdoctoral fellow in the Department of Civil and Environmental Engineering at HKUST, alongside collaborators from the University of Hawaiʻi at Mānoa, Sun Yat-Sen University and Nanjing University of Information Science and Technology.

Integrative quantum chemistry method unlocks secrets of advanced materials

A new computational approach developed at the University of Chicago promises to shed light on some of the world’s most puzzling materials—from high-temperature superconductors to solar cell semiconductors—by uniting two long-divided scientific perspectives.

“For decades, chemists and physicists have used very different lenses to look at materials. What we’ve done now is create a rigorous way to bring those perspectives together,” said senior author Laura Gagliardi, Richard and Kathy Leventhal Professor in the Department of Chemistry and the Pritzker School of Molecular Engineering. “This gives us a new toolkit to understand and eventually design materials with extraordinary properties.”

When it comes to solids, physicists usually think in terms of broad, repeating band structures, while chemists focus on the local behavior of electrons in specific molecules or fragments. But many important materials—such as organic semiconductors, metal–organic frameworks, and strongly correlated oxides—don’t fit neatly into either picture. In these materials, electrons are often thought of as hopping between repeating fragments rather than being distributed across the material.

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