A research study has discovered that nanometric-size foam structures follow the same universal laws as does soap lather: small bubbles disappear in favor of the larger ones. They reached this conclusion after producing and characterizing nanofoam formed by ion radiation on a silicon surface.
Phosphorus can be found in fertilizers, drinks and detergents, and it accumulates in waterways, polluting them. For this reason, researchers in Germany have developed a new platform for recovering this valuable but harmful element from water. They have attached bonding sites for phosphorus to particles so that they fish the phosphate anions out of the water and carry them “piggyback”. The particles can be applied using a magnet.
Groundbreaking work by a team of chemists on a fringe element of the periodic table could change how the world stores radioactive waste and recycles fuel. In carefully choreographed experiments, researchers in Florida have found that californium (Cf) had amazing abilities to bond and separate other materials. They also found it was extremely resistant to radiation damage.
Vertically aligned carbon nanofibers (VACNFs) are a commonly manufactured material, but conventional techniques for creating them have relied on the use of ammonia gas, which is toxic. Though it not costly, it is also not free, either. Researchers in North Carolina have demonstrated that VACNFs can be manufactured using ambient air, making the manufacturing process safer and less expensive.
An unwanted byproduct from a bygone method of glass production, the crystal devitrite could find a new use as an optical diffuser in medical laser treatments, communications systems and household lighting. For years, the properties of this material were not studied because it was considered as just a troublemaker in the glass-making process and needed to be eliminated.
Inspired by the framework structure of bones and the shell structure of bees’ honeycombs, researchers in Germany have developed microstructured lightweight construction materials of extremely high stability. Although its density is below that of water, the material’s stability relative to its weight exceeds that of massive materials, such as high-performance steel or aluminum. It was created using 3-D laser writing.
From super-lubricants, to solar cells, to the fledgling technology of valleytronics, there is much to be excited about with the discovery of a unique new 2-D semiconductor, rhenium disulfide, by researchers at Lawrence Berkeley National Laboratory’s Molecular Foundry. Rhenium disulfide, unlike molybdenum disulfide and other dichalcogenides, behaves electronically as if it were a 2-D monolayer even as a 3-D bulk material.
Ultrasound is a proven technology in components testing, but until now evaluating the data has always been quite a time-consuming process. Researchers in Germany have recently optimized an ultrasonic testing solution that can test materials quickly and reliably with the help of 3-D images produced directly from test signals. The solution is analogous to medical computed tomography.
Researchers in California have used a beam of intense ultraviolet light to look deep into the electronic structure of a material made of alternating layers of graphene and calcium. While it's been known for nearly a decade that this combined material is superconducting, the new study offers the first compelling evidence that the graphene layers are instrumental in this process. The finding could lead to super-efficient nanoelectronics.
Researchers from North Carolina State Univ. have developed a new processing technique that makes light-emitting diodes (LEDs) brighter and more resilient by coating the semiconductor material gallium nitride (GaN) with a layer of phosphorus-derived acid.
Researchers have succeeded for the first time to produce uniform antimony nanocrystals. Tested as components of laboratory batteries, these are able to store a large number of both lithium and sodium ions. These nanomaterials operate with high rate and may eventually be used as alternative anode materials in future high-energy-density batteries.
Researchers at the Harvard Univ. School of Engineering and Applied Sciences are giving man-made materials structural color. Producing structural color is not easy, though; it often requires a material’s molecules to be in a very specific crystalline pattern, like the natural structure of an opal, which reflects a wide array of colors.
Plants have many valuable functions: They provide food and fuel, release the oxygen that we breathe and add beauty to our surroundings. Now, a team of Massachusetts Institute of Technology researchers wants to make plants even more useful by augmenting them with nanomaterials that could enhance their energy production and give them completely new functions, such as monitoring environmental pollutants.
An ultra-fast and ultra-small optical switch has been invented that could advance the day when photons replace electrons in the innards of consumer products ranging from cell phones to automobiles. The new optical device can turn on and off trillions of times per second and consists of tiny individual switches made of a metamaterial that uses vanadium dioxide.
Particle counters are used in a wide variety of industries. Researchers in North Carolina have developed a new thermal technique that counts and measures the size of particles, but is less expensive than light-based techniques. It can also be used on a wider array of materials than electricity-based techniques.
Researchers have discovered that creating a graphene-copper-graphene “sandwich” strongly enhances the heat conducting properties of copper, a discovery that could further help in the downscaling of electronics.
Will one-atom-thick layers of molybdenum disulfide, a compound that occurs naturally in rocks, prove to be better than graphene for electronic applications? Recent research into phenomena occurring in the crystal network of this material show signs that might prove to be the case. But physicists in Poland have shown that the nature of the phenomena occurring in layered materials are still ill-understood.
Changing the texture and surface characteristics of a semiconductor material at the nanoscale can influence the way that neural cells grow on the material. The finding stems from a study performed by researchers at North Carolina State Univ., the Univ. of North Carolina at Chapel Hill and Purdue Univ., and may have utility for developing future neural implants.
Researchers have applied a novel microscopy technique to characterize metal-organic framework (MOF) materials, potentially opening a pathway for engineering the chemical properties of these materials at the nanoscale. MOFs are composed of metal ions connected by organic linker molecules to form 3-D-crystalline networks of nanopores with high surface areas, leading to applications in catalysis, chemical separation and sensing.
Thin films of spin ice have been shown to demonstrate surprising properties which could help in the development of applications of magnetricity, the magnetic equivalent of electricity. Researchers based at the London Centre for Nanotechnology, in collaboration with scientists from Oxford and Cambridge, found that, against expectations, the Third Law of Thermodynamics could be restored in thin films of the magnetic material spin ice.
Using little more than a few perforated sheets of plastic and a staggering amount of number crunching, Duke Univ. engineers have demonstrated the world’s first 3-D acoustic cloak. The new device reroutes sound waves to create the impression that both the cloak and anything beneath it are not there.
Graphene is not the only ultrathin material that exhibits special electronic properties. Ultrathin layers made of tungsten and selenium have recently been created in Austria that show a high internal efficiency when used to gather sunlight. More than 95% of light passes straight through, but a tenth of what is stopped is converted to electricity.
A team of Massachusetts Institute of Technology researchers has used a novel material that’s just a few atoms thick to create devices that can harness or emit light. This proof-of-concept could lead to ultra-thin, lightweight and flexible photovoltaic cells, light-emitting diodes (LEDs) and other optoelectronic devices, they say.
Experts from the Univ. of Buffalo (UB), helped by colleagues from two Chinese universities, have developed an optical "nanocavity" that could help increase the amount of light absorbed by ultrathin semiconductors. The advancement could lead to the creation of more powerful photovoltaic cells and improvements in video cameras and even hydrogen fuel, as the technology could aid the splitting of water using energy from light.
A new mechanism of controlling magnetic states by electric currents has been discovered by an international team of researchers who have exploited a quantum phenomenon to control magnetic states with electrical currents. The research hinges on a quantum geometrical phase, called the Berry phase, that exists in the momentum space of electronic band structures in specific materials.