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Category: materials

Plant-inspired water membrane filters CO₂ with constant selectivity and adjustable permeance

Gas separation membranes are vital for carbon capture, biogas upgrading, and hydrogen purification, all of which require the separation of carbon dioxide from gases like nitrogen, methane and hydrogen. However, the membranes currently in use for these applications suffer from limitations like low throughput or performance under high pressure and humidity, low gas flow, instability, and reaction rate limits.

Plants may have inspired a solution to many of these issues with the way their leaves absorb CO2. In a new study, published in Nature Communications, a team of researchers tests out a plant-inspired, water-based membrane that offers highly selective and permeable gas separation that outperforms many other materials, while also providing a greener, safer, and potentially cheaper way to capture CO2 and purify gases.

Carbon nanotube fiber sensors achieve record measurement error below 0.1%

Skoltech scientists, in collaboration with colleagues from China and Iran, have taken a major step toward creating highly precise carbon nanotube fiber (CNTF)-based sensors. In a paper published in the iScience journal, the authors, for the first time, quantitatively assessed the accuracy of CNTF sensors for dual-stage, i.e., manufacturing and post-manufacturing monitoring of epoxy-based polymer nanocomposites with dispersed CNTs.

The researchers emphasize that this development paves the way for creating a cutting-edge carbon-based material for high-precision and real-time sensing applications.

Existing monitoring sensors, such as fiber optics or piezoelectric sensors, are not suitable for the dual-stage monitoring of polymer composite materials. Additionally, embedding them into the composite structure often leads to deterioration in the mechanical properties of ready-made materials, making it more vulnerable to failure.

A centimeter-long bacterium with DNA contained in metabolically active, membrane-bound organelles

Volland et al. discovered a type of bacteria which grows to around a centimeter in length! They explore its remarkable biological adaptations as well. A very interesting read!

Candidatus Thiomargarita magnifica contains compartmentalized genomic material and disrupts conceptions of microbial morphology.

Parabolic flight test shows lasers can propel graphene aerogels in microgravity

Lasers could one day steer solar sails and adjust a satellite’s position in outer space, thanks to graphene. An experiment on a gravity rollercoaster ride showed how this innovative material has the potential to revolutionize propulsion beyond Earth.

An international research team boarded ESA’s 86th parabolic flight campaign in May 2025 with ultralight graphene aerogels, then hit them with light during zero gravity phases to observe their reaction under space-like conditions.

The effect of the laser during the microgravity phases was startling: The graphene samples shot forward instantly.

Metamaterial chains learn new shapes by sharing data hinge to hinge

In a new Nature Physics publication, University of Amsterdam researchers introduce human-made materials that spring to life. These ‘metamaterials’ don’t just learn to change shape, but can autonomously adapt their shape-changing strategy, perform reflex actions and move around like living systems do.

Normal materials have fixed, predetermined responses when a force is applied to them, whereas robots have pre-programmed behaviors. In stark contrast, living materials such as cells and brainless organisms can adapt extremely well to changing conditions. Inspired by nature, the research team created synthetic materials—metamaterials—that learn and adapt without a central “brain.”

The worm-like metamaterials progressively learn how to change shape by being trained on examples. They can forget old shapes and learn new ones, or learn and remember multiple shapes at once and toggle between these shapes. This allows them to perform advanced tasks such as grabbing an object or moving around (locomotion).

Water-repelling surfaces reveal surprising charging effects

Materials that repel water are used in countless applications, including industrial separation processes, routine laboratory pipetting, and medical devices. When water touches these surfaces, the interface where they meet tends to acquire a small electrical charge—an effect that is ubiquitous, yet poorly understood. KAUST researchers have now studied this in detail and their findings could have broad implications. The findings are published in the journal Langmuir.

“This is not a niche laboratory curiosity,” says Yinfeng Xu, a Ph.D. student who led the experimental work in Himanshu Mishra’s laboratory. “This phenomenon plays a role in environmental processes such as dew droplets and raindrops; in industrial operations involving sprays, condensates, or emulsions; and in modern microfluidic and liquid-handling systems used in laboratories worldwide.”

Stitching precise patterns—with lasers

Just as embroiderers, with needle and thread, can transform plain fabric into an intricate pattern, engineers can use lasers and polymers to create flexible, complex structures that could transform life-saving sensing technology. An interdisciplinary team at the University of Pittsburgh’s Swanson School of Engineering has developed a new manufacturing strategy that reveals where and how laser-induced graphene (LIG) forms on polymers.

The research opens new opportunities for flexible microelectrodes and neurochemical biosensors.

“Miniaturizing Laser-Induced Graphene for Biosensors by Spatial Control of Initiation and Side-Selective Microfabrication on Commercial Polymers” was selected as a cover feature in Issue 7 of the Advanced Materials Technologies, published in April 2026.

Scientists Discover Strange Property of Rice and Turn It Into a Smart Material

Rice behaves in an unexpected way under pressure. When compressed quickly, it becomes weaker, but under slow pressure it stays strong. This insight is helping scientists develop a new material that could be used in “soft” robots that automatically adjust stiffness, as well as protective gear that responds to how fast an impact occurs.

Using this property, researchers created a new type of “metamaterial,” an engineered structure designed to exhibit behaviors not found in natural materials.

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