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Category: chemistry

Nanopattern method unlocks precise control of disorder for wave-guiding devices

A research team has developed a methodology to precisely design and control the “degree of disorder” in nanopattern arrays using metal-infiltrated block copolymer (BCP) thin films. The work was led by Professor So Youn Kim of the Seoul National University College of Engineering Department of Chemical and Biological Engineering, in collaboration with Professor Su-Mi Hur’s team at DGIST and Professor S. Joon Kwon’s team at Sungkyunkwan University. The paper is published in the journal Nature Communications. The study was selected as an Editors’ Highlight in materials science and chemistry.

This disordered nanopattern fabrication technology is regarded as an innovative approach that enables precise control of nanoscale disorder structures—previously difficult to regulate—thereby opening new possibilities in the design of nano-optical and nanoelectronic devices.

In ordered structures, waves propagate over long distances, whereas in disordered structures, repeated scattering can lead to localization, where waves remain confined within a specific region. Such disordered structures exhibit unique functionalities that can induce localization phenomena for various types of waves, including light, sound and heat.

New study assesses Titan’s resources and their potential uses

Saturn’s largest moon, Titan, is a unique environment in our solar system. It is the only moon (or body beyond Earth) to have a dense, nitrogen-rich atmosphere, and its methane cycle is very similar to Earth’s hydrological cycle, in which solid and liquid methane evaporate to form clouds and return to the surface as precipitation. In addition, its prebiotic surface environment and rich organic chemistry make it a prime destination for astrobiology missions, such as NASA’s Dragonfly mission (set to launch no earlier than July 2028).

And as Robert Zubrin said in his book, “Entering Space: Creating a Spacefaring Civilization,” Saturn’s moons could become the “Persian Gulf” of the solar system, with Titan a major one because of its rich resource environment. In a recent NASA-supported study posted to the arXiv preprint server, a team of researchers compiled an inventory of Titan’s resources and their potential use by future generations of humans. When comparing this satellite with other destinations (i.e., the moon and Mars), they conclude that Titan offers several potential benefits for human settlement.

The research was led by Conor A. Nixon, an astronomer and planetary scientist with the solar system Exploration Division (SSED) at the NASA Goddard Space Flight Center and the associate laboratory chief of its Planetary Systems Laboratory. He was joined by Ye Lu, a professor of aerospace engineering at Worcester Polytechnic Institute, and Jennifer E. Ruliffson, a professor of Materials Science and Engineering at the University of Florida. Their paper is under review for publication in Acta Astronautica.

Chemical impurities make carbon surfaces superslippery, researchers find

Engineers often treat impurities as a problem to eliminate to improve material performance. But new research from Osaka Metropolitan University and Fraunhofer Institute for Mechanics of Materials IWM suggests that in some cases, a little chemical messiness is exactly what helps materials slide more smoothly. The findings were published in Advanced Science.

When two surfaces slide or rub against each other, friction occurs. While friction is essential for many everyday applications, it also wears down machines, wastes energy and limits the lifespan of moving parts. Therefore, research has focused on achieving superlow friction, or superlubricity, in which surfaces can slide past one another with exceptionally low resistance.

“While graphene-or graphite-like structures are known to enable nearly frictionless sliding, creating and maintaining such structures in practical systems remains challenging,” said Takuya Kuwahara, lecturer at Osaka Metropolitan University’s Graduate School of Engineering and lead author of the study.

When a pool or pond turns green with algae, don’t reach for chemicals—nature has better solutions

When the Lincoln Memorial Reflecting Pool turned green with algae just days after a US$15 million renovation, the U.S. government scrambled for chemicals and expensive technical solutions to fix the iconic landmark.

Trying to kill algae with chemicals is a common response when community ponds or other water features go green. But as a scientist who studies freshwater ecology, I can tell you there are better solutions that cost far less, last longer and carry less risk of harm to pets and wildlife.

Rather than battling against nature, these alternatives work with nature for long-term solutions.

What really controls water chemistry in nanoscale spaces

Water is the most studied molecule on Earth, yet a surprisingly basic question has gone unanswered for decades: When water is squeezed into gaps just a few molecules wide—as happens inside nanoscale pores, membranes and biological channels—does it become more or less chemically reactive?

This matters because water’s most fundamental chemical property is its ability to split into two charged species, H₃O⁺ (the hydronium ion) and OH⁻ (the hydroxide ion). This reaction defines the pH, a measure of how acidic or alkaline (basic) a solution is, and underpins all of acid-base chemistry, from how enzymes work in your cells to how electrodes function in batteries.

Through this research, the scientists wanted to understand whether (and how) confining water to nanometer-scale spaces affects this behavior.

Dead lithium batteries revived to 95% capacity via electrochemical bath

You know how rejuvenating a bath feels after a long day of work? Almost like you’re renewed. Turns out that’s not exclusive to humans. Scientists at Cornell University have developed an electrochemical bath that restores spent lithium-ion batteries to nearly 100% capacity.

Unlike conventional battery recycling methods that involve the complete physical destruction of batteries, followed by complex, energy-intensive recovery processes to extract critical battery-making materials, the scientists’ method recycles lithium-ion battery electrodes directly. Rather than breaking down structurally intact electrodes to extract materials that will make other electrodes, their approach regenerates the existing electrodes using an electrochemical solution.

The researchers say this method restored batteries to 95% of their original capacity, and even helped recycled batteries last longer. According to them, the method could also slash recycling costs by 56% while being more environmentally friendly.

Detect Dangerous Gases in Seconds With New Technology

A groundbreaking method known as coherently controlled quartz-enhanced photoacoustic spectroscopy has been developed to detect and identify gases at very low concentrations rapidly.

This new technique, with promising applications in environmental monitoring, early cancer detection, and chemical process safety, allows for comprehensive gas analysis in mere seconds, a process that traditionally took much longer.

Enhanced sensitivity in trace gas detection.

Metal hydride molecule trapped with laser light opens path to ultracold hydrogen

Controlling and trapping molecules, units of a substance consisting of two or more chemically bound atoms, with laser light is significantly more challenging than trapping individual atoms. This is because molecules exhibit more complex vibrational and rotational dynamics that make them more difficult to cool and trap.

In a paper published in Physical Review Letters, researchers at Columbia University and Indiana University Bloomington reported the effective cooling and trapping of calcium monohydride (CaH), a molecule consisting of a calcium atom and a hydrogen atom bound together.

This was achieved using a three-dimensional (3D) magneto-optical trap (MOT), a device that uses carefully arranged laser beams and magnetic fields to cool and confine particles.

Scientists discover how a single cell builds a brain with 170 billion cells

How does a single cell build a brain with billions of precisely organized neurons? Researchers suggest that brain cells use their lineage—their cellular family tree—as a kind of positional map. Cells that come from the same ancestor stay near one another, helping the brain organize itself without relying solely on chemical signals.

Modular coatings customize hydrogel implants to boost adhesion and limit fibrosis

Researchers led by Jiawei Yang, Worcester Polytechnic Institute (WPI) Assistant Professor in the Department of Mechanical and Materials Engineering, have designed a modular system that could potentially improve hydrogel implants in the body by customizing the materials for stiffness and functionality.

The system, described in the journal Science Advances, uses coatings to treat the surface of hydrogels, which are flexible, water-loaded polymers. The researchers reported that by customizing different types of hydrogels with unique coatings, they were able to create two distinct hydrogel implants that maintained adhesion in living tissue and resisted an immune system response.

“It is difficult for a material with a single chemical composition to play two distinct roles in an implant,” Yang said. “We addressed that by developing a way to customize hydrogel implants with two sets of chemical compositions that can be tailored to address specific needs and achieve better results.”

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