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Category: energy

Scientists create slippery nanopores that supercharge blue energy

Scientists have found a way to significantly boost “blue energy,” which generates electricity from the mixing of saltwater and freshwater. By coating nanopores with lipid molecules that create a friction-reducing water layer, they enabled ions to pass through much more efficiently while keeping the process highly selective. Their prototype membrane produced about two to three times more power than current technologies. The discovery could help bring osmotic energy closer to becoming a practical renewable power source.

Scalable quantum batteries can charge faster than their classical counterparts

Over the past decades, energy engineers have developed increasingly advanced battery technologies that can store more energy, charge faster and maintain their performance for longer. In recent years, some researchers have also started exploring the potential of quantum batteries, devices that can store energy leveraging quantum mechanical effects.

To store energy, quantum batteries rely on qubits, quantum systems that can exist in two energy states simultaneously, leveraging a property known as superposition. While in principle these batteries could perform better than classical batteries, the realization of battery prototypes that exhibit this predicted quantum advantage has proved challenging.

Researchers at the Southern University and Technology in China (Sustech) and the Superior Council for Scientific Research (CSIC) in Spain recently realized a quantum energy storage device that was found to outperform a classical equivalent when operating under realistic conditions.

Quantum materials could enable the solar-powered production of hydrogen from water

Hydrogen fuel is a promising alternative to fossil fuels that only emits water vapor when used and could thus help to lower greenhouse gas emissions on Earth. In the future, it could potentially be used to fuel heavy-duty transport vehicles, such as trucks, trains, and ships, as well as industrial heating and decentralized power generation systems.

Unfortunately, most current methods to produce hydrogen rely on the burning of fossil fuels, which limits its environmental advantages. Given its potential, many energy engineers worldwide have been trying to devise more sustainable strategies to produce hydrogen on a large scale.

One proposed method for the clean production of hydrogen is known as photocatalytic water splitting. This approach entails splitting water molecules into hydrogen and oxygen, using photocatalysts (i.e., materials that respond to sunlight and prompt desired chemical reactions).

NASA finds extreme star collision in unlikely spot

A fleet of NASA missions has likely uncovered a collision between two ultradense stars in a tiny galaxy buried in a huge stream of gas. Astronomers have never seen this type of explosive event in an environment like this before—and it may help solve two outstanding cosmic mysteries. A paper describing these results is forthcoming in The Astrophysical Journal Letters and currently available on the arXiv preprint server.

Neutron stars are the cores left behind after a star much heavier than the sun runs out of fuel, collapses on itself, and then explodes. They are small (only a dozen or so miles across) but slightly more massive than the sun, making them amazingly dense. Astronomers consider them to be some of the most extreme objects in the universe.

In recent years, astronomers have collected data on collisions, or mergers, of two neutron stars inside of moderately sized or large galaxies. This latest discovery, however, shows that a neutron star collision may take place inside a tiny galaxy.

Resolving Barrier Crossing in Protein Folding

High-temporal-resolution fluorescence measurements reveal how quickly proteins cross energy barriers separating unfolded and folded states.

Proteins are the active molecules of life. To carry out their functions, they adopt specific structures, or “folds.” Biophysicists have long been fascinated by the “protein-folding problem”: How does the sequence of amino-acid building blocks encode the protein’s ultimate fold, and how can folding occur so quickly and reliably? The folding process can be understood as a diffusive random walk through the large space of possible configurations, culminating in the crossing of an energy barrier to reach the folded state. The time spent exploring unfolded configurations can span many orders of magnitude and has been measured with various experimental techniques. By contrast, the comparatively short time to ultimately cross the energy barrier—known as the transition-path time—had never been measured in a naturally occurring protein under biologically relevant conditions.

Scientists harness quantum tunneling to boost heavy water production efficiency

A study by scientists at Hunan University introduces a new hydrogen isotope separation method that leverages proton quantum tunneling to produce heavy water, overcoming the key physical limitation faced by current methods that have made the production process difficult and expensive for decades.

According to results published in Proceedings of the National Academy of Sciences, this new strategy achieves a record-high H2O separation factor of 276 at room temperature by designing through-barriers that allow hydrogen nuclei to pass through them via quantum tunneling, leaving deuterium behind.

By leveraging quantum mechanics, the method could pave the way for cleaner and more efficient production of a critical material for future energy technologies.

3D-printed photonic lanterns combine up to 37 multimode lasers into one fiber

Researchers have developed a microscopic 3D-printed optical device that can efficiently combine light from dozens of small semiconductor lasers into a single multimode optical fiber with very low loss. The team demonstrated photonic lanterns that multiplex 7, 19, and 37 multimode VCSEL lasers directly into a fiber while preserving brightness and easing alignment constraints. By enabling scalable incoherent beam combining of many multimode lasers, the technology could simplify and improve high-power laser systems, optical communications, and other photonic applications where efficiently delivering large optical power through fibers is critical.

A new study published in Nature Communications by Ph.D. student Yoav Dana, under the guidance of Professor Dan M. Marom and his team at the Institute of Applied Physics at the Hebrew University of Jerusalem, Israel, demonstrate a significant breakthrough in system scale and miniaturization for an optical beam combining apparatus, as those required in high-power laser systems.

The research, conducted in collaboration with Civan Lasers, introduces a novel 3D-printed microscale Photonic Lantern (PL) designed for the efficient incoherent combining of multimode sources. This innovation addresses the long-standing challenge of coupling light from large Vertical-Cavity Surface-Emitting Laser (VCSEL) arrays, each of said VCSEL sources being multimoded, into multimode fibers (MMFs) while preserving the brightness and modal capacity of the system.

2D topological Kondo insulator observed in a moiré superlattice

When mobile charge carriers, also known as itinerant electrons, interact with the strong exchange magnetic fields associated with the intrinsic angular momentum of localized electrons, this can give rise to the so-called Kondo effect. A Kondo insulator is a state of matter with an energy gap opened by the Kondo effect that forbids electrical conduction at low temperatures.

Like Kondo insulators, topological Kondo insulators are materials that behave as insulators (i.e., not conducting electricity) in their interior, but, unlike their counterparts without topology, can conduct electricity at their surface or edges. This unique, quantum phase of matter is protected by a material’s internal symmetry and topology; thus, it is not easily disrupted.

So far, hints of this phase have been primarily observed in 3D quantum materials, such as samarium hexaboride (SmB₆) and ytterbium dodecaboride. Some physicists and material scientists have also been exploring the possible existence of this phase in 2D structures comprised of two materials stacked with a slight mismatch between them, producing a pattern known as a moiré superlattice.

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