(Funded by the U.S. Department of Energy)
Researchers from Rice University; the Massachusetts Institute of Technology; Carnegie Mellon University; the National University of Singapore; Southern University of Science and Technology in Shenzhen, China; and Osaka University in Japan have found a two-dimensional (2D) carbon material that is tougher than graphene and resists cracking. Carbon-derived materials, such as graphene, are among the strongest on Earth, but once established, cracks propagate rapidly through them, making them prone to sudden fracture. The new carbon material, called a monolayer amorphous carbon, is both strong and tough. Like graphene, this material is also a 2D material, but unlike graphene, in which atoms are arranged in an ordered lattice, this material incorporates both crystalline and amorphous regions. “This unique design prevents cracks from propagating easily, allowing the material to absorb more energy before breaking,” said Bongki Shin, one of the researchers involved in this study.

(Funded by the U.S. National Science Foundation)
Researchers at North Carolina State University have demonstrated a new technique that uses light to tune the optical properties of quantum dots. The researchers placed green-emitting perovskite quantum dots in a solution containing either chlorine or iodine. The solution was then run through a microfluidic system that incorporated a light source. The microfluidic environment enabled precise reaction control by ensuring uniform light exposure across small solution volumes, approximately 10 microliters per reaction droplet. The light triggered reactions that made the green-emitting perovskite quantum dots move closer to the blue end of the spectrum when chlorine was present in the solvent and closer to the red end of the spectrum when iodine was present in the solvent.

(Funded by the U.S. Department of Energy)
Scientists from the U.S. Department of Energy’s (DOE) Argonne National Laboratory, SLAC National Accelerator Laboratory, and Lawrence Berkeley National Laboratory; the University of California, Berkeley; Pennsylvania State University; Stanford University; Rice University; the Indian Institute of Science in Bangalore, India; the Japan Synchrotron Radiation Research Institute in Sayo, Japan; RIKEN SPring-8 Center in Sayo, Japan; and the University of Tokyo in Japan are investigating a material with a highly unusual structure – one that changes dramatically when exposed to an ultrafast pulse of light from a laser. At the Center for Nanoscale Materials, a DOE Office of Science user facility at Argonne, the scientists used a technique called transient absorption spectroscopy to detect photocarrier activity within the material. This approach helped them determine how much charge gets released and how quickly the charge decays.

(Funded by the U.S. National Science Foundation)
Engineers from Purdue University and GRIMM Aerosol Technik Ainring GmbH & Co. in Germany have found that chemical products from air fresheners, wax melts, floor cleaners, and deodorants can rapidly fill the air with nanoparticles that are small enough to get deep into our lungs. These nanoparticles form when fragrances interact with ozone, which enters buildings through ventilation systems. “Our research shows that fragranced products are not just passive sources of pleasant scents—they actively alter indoor air chemistry, leading to the formation of nanoparticles at concentrations that could have significant health implications,” said Nusrat Jung, one of the engineers involved in this study.

(Funded by the U.S. Department of Energy)
Most optical sensors record data from light and then transmit all of the raw data to a computer for processing. This typically consumes more energy than necessary, because in most applications, only a small amount of information relative to the raw data is needed. So, scientists from the U.S. Department of Energy’s Lawrence Berkeley National Laboratory and Sandia National Laboratories; the University of California, Berkeley; the University of California, Davis; and the University of Texas at Arlington are developing a less power-hungry approach, in which some data processing is conducted in the sensor itself, before the data is sent to a computer or processed by edge computing devices. The new sensor, called a “nanoscale hybrid,” stitches together nanostructures, such as nanotubes and nanowires. It is highly sensitive in part because the sensor’s nanoscale components are smaller than the wavelength of light.

(Funded by the U.S. Department of Defense and the U.S. Department of Energy)
Researchers from Rice University, the University of California Berkeley, the University of Pennsylvania, and the Massachusetts Institute of Technology have shed light on how the extreme miniaturization of thin films affects the behavior of relaxor ferroelectrics — materials with noteworthy energy-conversion properties used in sensors, actuators, and nanoelectronics. The findings reveal that as the films shrink to dimensions comparable to internal polarization structures within the films, their fundamental properties can shift in unexpected ways. More specifically, when the films are shrunk down to a precise range of 25–30 nanometers, their ability to maintain their structure and functionality under varying conditions is significantly enhanced.

(Funded by the U.S. Department of Agriculture and the National Institutes of Health)
Researchers from Rutgers University, the New Jersey Institute of Technology, the Connecticut Agricultural Experiment Station in New Haven, CT, and the Environmental and Occupational Health Sciences Institute in Piscataway, NJ, have shown that microplastic and nanosplastic particles in soil and water can significantly increase how much toxic chemicals plants and human intestinal cells absorb. Using a cellular model of the human small intestine, the researchers found that nano-size plastic particles increased the absorption of arsenic by nearly six-fold compared with arsenic exposure alone. The same effect was seen with boscalid, a commonly used pesticide. Also, the researchers exposed lettuce plants to two sizes of polystyrene particles – 20 nanometers and 1,000 nanometers – along with arsenic and boscalid. They found the smaller particles had the biggest impact, increasing arsenic uptake into edible plant tissues nearly threefold compared to plants exposed to arsenic alone.

(Funded by the U.S. Department of Energy)
Researchers from the U.S. Department of Energy’s Argonne National Laboratory and Fermi National Accelerator Laboratory, as well as Northern Illinois University have discovered that superconducting nanowire photon detectors, which are used for detecting photons (the fundamental particles of light) could potentially also function as highly accurate particle detectors, specifically for high-energy protons used as projectiles in particle accelerators. The ability to detect high-energy protons with superconducting nanowire photon detectors has never been reported before, and this discovery widens the scope of particle detection applications.

(Funded by the U.S. National Science Foundation)
Researchers at Washington University in St. Louis have developed ultra-thin materials, called metasurfaces, that can amplify and interact with light regardless of its polarization. The metasurfaces are made of tiny nanoantennas that can both amplify and control light in very precise ways and could replace conventional refractive surfaces in eyeglasses and smartphone lenses. The polarization-independent metasurfaces have what’s known as a high quality factor, which means they trap light over a narrow band of resonant frequencies for a long time, generating a strong response to external stimuli.

(Funded by the U.S. National Science Foundation)
Researchers from Northwestern University have defined a method to tailor a sponge that is coated with nanoparticles to specific Chicago pollutants and then to selectively release them. In its first iteration, the sponge platform was made of polyurethane and coated with a substance that attracted oil and repelled water. The newest version is a highly hydrophilic (water-loving) cellulose sponge coated with nanoparticles tailored to other pollutants. The scientists found that by lowering the pH, metals flush out of the sponge. Once copper and zinc are removed, the pH is then raised, at which point phosphate comes off the sponge. Even after five cycles of collecting and removing minerals, the sponge worked just as well, and the resulting water had untraceable amounts of pollutants.