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Category: chemistry

Electron matter waves gain ultrafast torque that flips handedness in femtoseconds

Many natural processes, ranging from magnetism to chemical reactions, entail the movement and rotation of particles at very small scales. In quantum mechanics, particles exhibit both particle-like and wave-like behaviors, and their states can be described mathematically using representations known as wavefunctions.

The reliable manipulation of wave-like properties of particles as small as atoms or single electrons could open new possibilities both for studying matter and for engineering materials with desirable characteristics. Notably, controlling the angular momentum, which is the quantum property related to rotational motion, of ultrasmall particles at ultrafast timescales has so far proved very challenging when only using conventional, laser-based approaches.

Researchers at Universität Konstanz recently devised a new approach to create electron beams with an ultrafast internal torque (i.e., twisting motion). Their proposed strategy, outlined in a paper published in Nature Physics, could be a promising tool for exploring material dynamics and quantum phenomena at atomic and subatomic scales.

CO₂ injection reveals hidden cement chemistry behind 13% stronger early strength

One September day, it started to snow inside MIT’s Pierce Laboratory. Researchers depressurized a tank of liquid carbon dioxide (CO2), instantly freezing it and releasing solid flakes. These were blended into cement paste and pressed into disks roughly the size of a dime, each sealed with a thin layer of vegetable oil to keep water in and air out. The team trained lasers on each one, observing for the first time the transient chemical reaction that might explain why CO2-injected cement paste gains strength faster.

Injecting CO2 into cement products like concrete is one way to store it and keep it out of the atmosphere. The process has attracted commercial interest, with a growing number of companies offering CO2-injected concrete mixes. But until now, the underlying cement chemistry hadn’t been directly visualized.

A new paper in the Journal of the American Ceramic Society —led by associate professor Admir Masic and first-authored by graduate student Marcin Hajduczek, both of the MIT Concrete Sustainability Hub and MIT Department of Civil and Environmental Engineering—describes the chemical sequence that unfolds after CO2 meets fresh cement paste. Co-authors include MIT colleagues Santiago El Awad and Franz-Josef Ulm, alongside researchers from IIT Jodhpur and CarbonCure Technologies.

How Life Learned to Think: The Complete History of Intelligence

Your brain is running on twenty watts right now. The power of a dim lightbulb. And yet it contains the entire eight-hundred-million-year history of life’s most improbable experiment — the experiment of intelligence itself. In this episode, we follow that experiment from its very beginning: from the first bacterium that navigated a chemical gradient in the ancient ocean, through the nerve nets of jellyfish, the distributed arms of the octopus, the tool-making crow, the grieving elephant, the dreaming mammalian brain — all the way to the only creature that has ever turned its intelligence on the question of where intelligence came from. This is not a story about the human brain. It is a story about what matter does when evolution pressures it long enough and hard enough. It is the deepest origin story you have.

/ @theevolutionoflife2026 Subscribe to the channel and join us — there is much more of this story still to tell.

CRISPR enzyme precisely detects and shreds DNA in cancer mutations once considered ‘undruggable’

In 2020, Jennifer Doudna won the Nobel Prize in chemistry for her work on the CRISPR-Cas9 gene-editing technology that allows scientists to precisely modify DNA by cutting it at specific locations. Six years later, a new study in Nature by a team led by Doudna has uncovered a powerful new approach to selectively kill cancer cells using a CRISPR enzyme called Cas12a2.

Once the enzyme detects cancer-specific genetic signatures, it begins to shred chromatin—a mixture of DNA and proteins that forms chromosomes—within the targeted cell.

Many cancers are driven by mutations in tumor suppressor proteins such as TP53, which is altered in nearly half of all cases. Yet these mutations have remained difficult to treat because they lack binding pockets for traditional drugs to latch onto. As a result, many cancer-causing mutations have long been considered undruggable.

Bioscience Breakthrough Turns Plant Waste Into Gasoline

KU Leuven, Belgium bioscience engineers have developed a roadmap, so to speak, for industrial cellulose gasoline.

The bioscience engineers already knew how to make gasoline in the laboratory from plant waste such as sawdust. In 2014, at KU Leuven’s Centre for Surface Chemistry and Catalysis, the researchers succeeded in converting sawdust into building blocks for gasoline.

A chemical process made it possible to convert the cellulose – the main component of plant fibers – in the sawdust into hydrocarbon chains. These hydrocarbons can be used as an additive in gasoline. The resulting cellulose gasoline is a second-generation biofuel.

New buried-growth process enables 2D arrays of position- and orientation-controlled diamond qubits

Researchers at Kanazawa University, in collaboration with Diamond and Carbon Applications (Germany), have developed a buried-growth process for nitrogen–vacancy (NV) centers in diamond using microwave plasma chemical vapor deposition (MPCVD). By employing nitrogen-radical selective etching, which simultaneously enhances metal-mask durability through nitridation, the team enabled a continuous etching–growth sequence within a single MPCVD process.

The work is published in the journal Carbon.

Optical measurements confirmed highly aligned NV centers selectively buried in predefined regions. This integrated approach provides a stable and scalable platform for orientation-controlled diamond qubits and future room-temperature quantum technologies.

Water locked in 1-nanometer channels could enable safer energy storage

Can pure water store electrical energy? A research team led by Dr. Vasily Artemov within the Cluster of Excellence “BlueMat—Water-Driven Materials” at Hamburg University of Technology has now shown that it can. By confining water within nanometer-sized channels in clay minerals, the researchers created a supercapacitor capable of efficiently storing and transporting electrical charge.

What makes the finding unusual is that it uses pure water as its electrolyte—the medium that transports electrical charge. Today’s batteries and supercapacitors typically rely on added salts, acids, or other chemical electrolytes. In contrast, the new system works without such additives and is based solely on abundant, naturally occurring materials: water, clay, and carbon.

“Our goal is to develop safer and more sustainable energy-storage technologies based on abundant materials rather than complex chemical compounds,” says Artemov, lead author of the paper published in Nature Communications. “The device stores and releases energy efficiently, operates at a comparatively high voltage for a water-based system, and remains stable over tens of thousands of charging cycles.”

Claude Fable 5 and Claude Mythos 5

While Mythos 5 remains largely unconstrained for restricted government and trusted enterprise partners, Fable 5 is wrapped in a sophisticated safety perimeter. If Fable 5 detects a prompt drifting toward high-risk vectors—like cyberwarfare exploits, advanced biology, or chemical synthesis—it doesn’t just give a generic “I can’t answer that” error. Instead, the query seamlessly falls back to Claude Opus 4.8 (Anthropic’s next-most capable model) to handle the response safely.

Today we’re launching Claude Fable 5: a Mythos-class1 model that we’ve made safe for general use.

Fable 5’s capabilities exceed those of any model we’ve ever made generally available. It is state-of-the-art on nearly all tested benchmarks of AI capability, showing exceptional performance in software engineering, knowledge work, vision, scientific research, and many other areas. The longer and more complex the task, the larger Fable 5’s lead over our other models.

Releasing a model this capable comes with risks. Without safeguards, Fable 5’s capabilities in areas like cybersecurity could be misused to cause serious damage. We’ve therefore launched the model with safeguards that mean queries on some topics will instead receive a response from our next-most-capable model, Claude Opus 4.8. To release the model both safely and quickly, we’ve tuned these safeguards conservatively—they’ll sometimes catch harmless requests, though they trigger, on average, in less than 5% of sessions. With more capable models arriving in the coming months, we’re working to improve our safeguards and reduce false positives as quickly as we can.

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