Creating biohybrid robots—machines powered by lab-grown muscle tissue—has long been a goal for scientists aiming to build more adaptable, flexible robots. These robots could potentially squeeze and twist through spaces that are too small or complex for traditional machines. However, a significant challenge has stood in the way: existing artificial muscles typically only contract in one direction, limiting their range of motion. Imagine a robot with an arm that can only flex but can never rotate—this limitation has been a key obstacle.

Now, researchers at MIT have cracked the code for creating a new type of artificial muscle capable of complex, multi-directional movement. In a groundbreaking development, they’ve created artificial muscle fibers that can move in multiple directions, mimicking the behavior of the iris in a human eye. To prove their concept, the team designed a muscle-powered structure that contracts both in a circular and outward direction, showcasing a level of motion that previous biohybrid robots couldn’t achieve.

A team of researchers from Carnegie Mellon University has recently developed a groundbreaking method for producing large quantities of a material that could revolutionize the field of two-dimensional (2D) semiconductors. Their work, published in ACS Applied Materials & Interfaces in December 2024, promises to enhance the performance of photodetectors and pave the way for the next generation of light-sensing and multifunctional optoelectronic devices.

Semiconductors are at the heart of modern electronics, powering everything from smartphones and laptops to AI technologies. These materials control the flow of electricity by acting as a bridge between conductors (which allow electricity to flow freely) and insulators (which block it). According to Xu Zhang, assistant professor of electrical and computer engineering at Carnegie Mellon, the work done by his team is vital to advancing electronics and optoelectronics.

Supersolids, a bizarre and fascinating quantum state of matter, have now taken a new, mind-bending form: light itself. In a groundbreaking experiment, scientists have successfully transformed light into a supersolid, a development that could pave the way for advancements in quantum and photonic technologies.

Supersolids, a state previously only observed in atoms, combine the ordered structure of solids with the free-flowing properties of liquids. These extraordinary materials defy traditional classifications of matter, offering a crystalline arrangement like a solid while also exhibiting the fluid-like ability to flow without losing their shape—something that seems counterintuitive at first glance.

The Fengning Pumped Storage Power Station, located just north of Beijing, is officially up and running as of 2025. After over 11 years of construction and an investment of $2.6 billion, the station is now the largest of its kind globally, surpassing the previous record-holder in Bath County, Virginia, according to the International Hydropower Association (IHA).

Pumped-storage hydropower stations are often referred to as “water batteries” because they offer a reliable method for storing renewable energy, such as wind and solar power, which can be intermittent. By storing this excess energy, the grid experiences less stress, reducing the likelihood of blackouts. The Fengning station, for instance, supports a nearby wind and solar farm, contributing to the efficient use of clean energy.

D-Wave Quantum Inc., a Canadian company based in Vancouver specializing in quantum computing for commercial use, has made a groundbreaking achievement with its D-Wave Advantage 2 prototype annealing quantum computer. The company announced the success of solving a real-world, practical problem and validated its results through a peer-reviewed paper published in a prestigious scientific journal.

For decades, Moore’s Law has driven the rapid growth of microchip performance, with computing power doubling roughly every two years. This relentless advancement has drastically changed the landscape of computing, making devices smaller and more powerful. Despite this progress, however, many complex problems—such as climate change modeling and drug discovery—remain beyond the capabilities of even the most advanced supercomputers. In response to this challenge, quantum computing, which harnesses the principles of quantum mechanics, is poised to offer solutions to problems that could take current supercomputers years to solve.

On the morning of Saturday, March 29, the northeastern coast of North America will witness a rare and striking celestial event—a partial solar eclipse. As the sun rises, a crescent-shaped sun will appear on the eastern horizon, with the eclipse already in progress.

Thirteen U.S. states will experience the March 29 eclipse, though the intensity of the eclipse will vary depending on location. The farther northeast you go, the deeper the eclipse will be, with coastal New England offering the best views. In Maine, observers can expect up to 86% of the sun to be obscured at sunrise. New Hampshire and Massachusetts will see slightly less, with up to 57% and 55% coverage, respectively. In Boston, the eclipse will cover 43% of the sun.

Modern communication networks rely heavily on optical signals to transmit massive amounts of data. However, just like weak radio signals, these optical signals need amplification to travel long distances without degrading. For decades, erbium-doped fiber amplifiers (EDFAs) have been the go-to solution, extending transmission ranges without requiring frequent signal regeneration. While effective, EDFAs are limited by their narrow spectral range, which has hindered the expansion of optical networks.

With the increasing demand for high-speed data transmission—driven by advancements in AI accelerators, data centers, and high-performance computing—the limitations of traditional optical amplifiers are becoming more apparent. As a result, researchers are turning their attention to developing more powerful, flexible, and compact amplifiers to meet the rising data needs.