minerals

Say ‘Ahhhh’ – imagine your doctor monitoring a health condition from afar or emergency responders receiving real-time alerts that could save a life. A new smart sensor is taking the ouch out of wound monitoring. By using laser-induced graphene (LIG), a two-dimensional (2D) material, researchers are developing a sensor that could revolutionize the tracking of wound healing and recovery. Doctors could get a much clearer picture of the healing process, identifying issues like inflammation, physical strain or a spike in body temperature early on. "This unique sensor material we've developed has potentially important applications in health care monitoring,” said Huanyu “Larry” Cheng, James L. Henderson, Jr. Memorial Associate Professor of Engineering Science and Mechanics (ESM) at Penn State. LIG sensors are self-powered which means they could be especially useful for continuous monitoring in clinical settings or helping detect fires in remote locations. Source: Materials Research Institute, Penn StateUnder the Sea – Mechanical engineers at Carnegie Mellon’s Soft Machines Lab have created a soft robot inspired by the quick and agile brittle starfish, the first mobile and untethered underwater crawling robot. Named after Sponge Bob Square Pants’ sidekick, PATRICK is an AI powered robot which operates without motors so as not to disturb delicate sea life. To make the robot move, the researchers hit it with electric current, causing the wires to heat up past its transition temperature and allowing the limbs to contract and move in different directions. “We want to put the power and the electronics on-board with the robots,” said Ph.D. candidate and PATRICK creator, Zach Patterson. The soft robotic systems which are ideal for tracking the health and quality of water, are biodegradable to eliminate waste and protect the natural environment.Source: Carnegie Mellon University, School of Engineering The sky is NOT the limit with engineering – While Blue Origin made the news recently for sending an all women crew to the edge of space, the first Mexican born woman to travel into space is Katya Echazarreta, an electrical engineer originally from Guadalajara, Mexico. Echazarreta was selected for the trip from a pool of 7,000 applicants from more than 100 countries based on her outstanding achievements in the space industry, including five NASA missions. She traveled to space in 2022 aboard Blue Origin’s NS-21 flight as one of Space for Humanity’s citizen astronauts. Echazarreta comes from a family of engineers and works to make space exploration accessible to young kids, teens, women, and other scientists and engineers through Fundación Espacial, a foundation started in Mexico. Source: Astronomy.comMargaret Kindling is Senior Program Manager at the SEMI Foundation. She promotes inclusive workplaces via initiatives including Women in Semiconductors, Semiconductor PRIDE and workforce and career development programming at SEMICON West and SEMIEXPO Heartland.

Superconducting Naturally – Miassite is a naturally occurring mineral which scientists at Ames National Laboratory have identified as the first unconventional superconductor found in nature. Unlike conventional superconductors that follow the Bardeen-Cooper-Schrieffer (BCS) theory, minerals such as miassite exhibit unique properties outside of this framework. Made of rhodium and sulfur, miassite was initially recognized as a regular superconductor in 2010. Recent tests confirm it joins a small, exclusive group of unconventional superconductors previously limited to lab-made materials.Lab tests on miassite involved measuring magnetic reactions, inducing defects, and analyzing energy gaps, all confirming its unconventional behavior. While naturally occurring, samples are unlikely to be superconductive due to their disordered state, miassite’s lab-verified properties open doors to new research and highlight its unique duality as both a conventional and unconventional superconductor.Source: A Superconductor Found in Nature Has Rocked the Scientific WorldPheromones + vision = mate selection – When choosing a mate, Heliconius butterflies, despite their tiny brains can outperform current AI in multi-sensory decision-making by processing visual and chemical cues simultaneously. This discovery inspired Penn State researchers to develop a low-energy, multi-sensory AI platform using 2D materials. The device combines molybdenum sulfide (MoS2) to mimic visual capabilities and graphene to detect chemical signals like pheromones.The device could integrate visual and chemical cues, offering adaptability like a butterfly’s mating behavior. This innovation addresses limitations in current AI, which relies heavily on energy-intensive, single-sensory processes. Researchers aim to expand the device to process three senses, like crayfish using visual, tactile, and chemical cues. The work, supported by the U.S. Army Research Office and the U.S. National Science Foundation, could revolutionize applications in robotics, smart sensors, and critical environments, by enabling AI systems to detect issues using multiple sensory inputs efficiently. Imaging of Heliconius Butterfly A Butterfly Effect – Proving once again that there is a lot to be learned from nature, researchers from the Fraunhofer Institute for Solar Energy Systems ISE have developed innovative, colored solar facade elements inspired by morpho butterfly mimicry. These panels are aesthetically pleasing, integrate seamlessly into building exteriors, and retain high efficiency, achieving 95% of the power output of uncoated panels. Using vacuum-applied 3D photonic structures like those on butterfly wings, the panels produce vibrant, angularly stable colors with minimal energy loss. This MorphoColor® technology addresses architects’ and building owners’ concerns about design, offering an efficient, visually appealing solution for building-integrated photovoltaics while surpassing other technologies currently available.Close up of a morpho butterfly wingSustainable Flight – The world’s fastest supercomputer, Frontier, located at Oak Ridge National Laboratory, enables unprecedented advancements in sustainable aviation technology. Capable of over a quintillion calculations per second, Frontier allows GE Aerospace to conduct full-scale simulations of its revolutionary Open Fan engine design, accelerating insights into aerodynamics and turbulence. This groundbreaking tool aids the CFM RISE program, which aims to cut fuel consumption and CO2 emissions by at least 20%. Frontier’s detailed simulations predict engine performance under real-world conditions, saving years of testing. The partnership between GE Aerospace and Oak Ridge is expanding, promising future collaborations in climate modeling and advanced simulation techniques.An Open Fan engine design developed as part of a new project led by GE AerospaceSource: https://www.geaerospace.com/news/articles/new-frontier-how-ge-aerospace-using-worlds-fastest-supercomputer-help-design-open-fanMargaret Kindling is Senior Program Manager at the SEMI Foundation. She promotes inclusive workplaces via initiatives like Women in Semiconductors, Semiconductor PRIDE and workforce development programming at SEMICON West and SEMIEXPO Heartland.