Chemists have made a groundbreaking breakthrough in developing a novel method to generate highly useful chemical building blocks by harnessing metal carbenes. This achievement is expected to revolutionize the synthesis of life-saving drugs and materials development.

Typically used in chemical reactions essential for drug synthesis, carbenes are short-lived, highly reactive carbon atoms. However, creating these carbenes has been a challenging task due to limited methods and hazardous procedures.

Researchers at The Ohio State University have now developed an approach that makes producing metal carbenes much easier and safer. According to David Nagib, co-author of the study and distinguished professor in arts and sciences, “Our goal all along was to determine if we could come up with new methods of accessing carbenes that others hadn’t found before.”

The team’s innovative method uses iron as a metal catalyst and combines it with chlorine-based molecules that easily generate free radicals. This combination works to form the carbene of their choice, including many that had never been made before.

These three-sided molecular fragments, known as cyclopropanes, are vital to the synthesis of medicines and agrichemicals due to their small size and unusual energy. The researchers’ work was inspired by looking for the best ways to create these shape, which is one of the most common found in medicines.

“Our lab is obsessed with trying to get the best methods for making cyclopropanes out there as soon as possible,” said Nagib. “We have the eye on the prize of inventing better tools to make better medicines, and along the way, we’ve solved a huge problem in the carbene world.”

The study was recently published in Science, and the team’s discovery is expected to become extremely impactful. By accessing a new way of creating and classifying carbenes, scientists can simplify and improve the current wasteful, multistep process of producing them.

For consumers, this method suggests that future drugs developed by this technology may be cheaper, more potent, faster-acting, and longer-lasting. The work could prevent shortages of important medicines like antibiotics and antidepressants, as well as drugs that treat heart disease, COVID, and HIV infections, said Nagib.

Additionally, the team would like to ensure that their transformational organic chemistry tool is accessible to both big and small research labs and drug manufacturers around the world. One way to guarantee this is by continuing to improve the current technique, said Nagib.

“Our team at Ohio State came together in the coolest, most collaborative way to develop this tool,” he said. “So we’re going to continue racing to show how many different types of catalysts it could work on and make all kinds of challenging and valuable molecules.”

The study published in Royal Society Open Science presents a groundbreaking approach to understanding the mechanical properties of crystals. Researchers from The University of Osaka have successfully used differential geometry to provide a unified description for the mechanics of crystals and their defects. This breakthrough has significant implications for the development of new materials with enhanced strength and durability.

Crystals, renowned for their beauty and elegance, often appear perfect on the outside. However, upon closer examination, they contain small defects in their structure – missing atoms or extra bonds. These imperfections have important mechanical consequences, as they can serve as starting points for fractures or even be used to strengthen materials. Understanding defects and their phenomena is crucial for researchers.

The study’s lead author, Shunsuke Kobayashi, notes that “defects come in many forms.” For instance, there are dislocations associated with the breaking of translational symmetry and disclinations associated with the breaking of rotational symmetry. Capturing all these types of defects within a single mathematical theory is not straightforward.

Previous models have struggled to reconcile the differences between dislocations and disclinations, indicating that modifications to the theory are needed. The research team found that new mathematical tools using differential geometry proved to be exactly what was required to address these issues.

Differential geometry provides an elegant framework for describing these complex phenomena. Simple mathematical operations can capture these effects, allowing researchers to focus on the similarities between seemingly disparate defects. Using the formalism of Riemann-Cartan manifolds, the team elegantly encapsulated the topological properties of defects and rigorously proved the relationship between dislocations and disclinations.

In addition, they derived analytical expressions for the stress fields caused by these defects. The research team hopes that their geometric approach to describing the mechanics of crystals will eventually inspire scientists and engineers to design materials with specific properties by taking advantage of defects, such as the strengthening of materials seen with disclinations. This breakthrough is yet another example of how beauty in mathematics can help us understand beauty in nature.

Imagine a world where technology could reveal hidden secrets just like magic. Scientists have made a breakthrough in creating artificial optical structures called metasurfaces that can control the way they interact with polarized light. This innovation has potential applications in data encryption, biosensing, and quantum technologies.

The team from the Bionanophotonic Systems Laboratory at EPFL’s School of Engineering collaborated with researchers in Australia to create a “chiral design toolkit” that is elegantly simple yet powerful. By varying the orientation of tiny elements called meta-atoms within a 2D lattice, scientists can control the resulting metasurface’s interaction with polarized light.

The innovation was showcased by encoding two different images on a metasurface optimized for the invisible mid-infrared range of the electromagnetic spectrum. The first image of an Australian cockatoo was encoded in the size of the meta-atoms, which represented pixels, and could be decoded with unpolarized light. The second image of the Swiss Matterhorn was encoded using the orientation of the meta-atoms, so that when exposed to circularly polarized light, the metasurface revealed a picture of the iconic mountain.

“This experiment showcased our technique’s ability to produce a dual layer ‘watermark’ invisible to the human eye, paving the way for advanced anticounterfeiting, camouflage and security applications,” says Ivan Sinev, researcher at the Bionanophotonics Systems Lab.

Beyond encryption, the team’s approach has potential applications in quantum technologies, where polarized light is used to perform computations. The ability to map chiral responses across large surfaces could also streamline biosensing.

“We can use chiral metastructures like ours to sense, for example, drug composition or purity from small-volume samples. Nature is chiral, and the ability to distinguish between left- and right-handed molecules is essential, as it could make the difference between a medicine and a toxin,” says Felix Richter, researcher at the Bionanophotonic Systems Lab.

This breakthrough has opened doors to new possibilities in data encryption, biosensing, and quantum technologies. The future of technology is indeed bright, and twisted light just got a whole lot more interesting.