A team at Purdue Univ. has used gold nanoparticles to target and bind to fragments of genetic material known as BRCA1 messenger RNA splice variants, which can indicate the presence and stage of breast cancer. The number of these synthetic DNA “tails” in a cell can be determined in a living cell by examining the specific signal that light produces when it interacts with the gold nanoparticles.
In the quest to make sun power more competitive, researchers are designing ultra-thin solar...
Rolls-Royce researchers came to SLAC National Accelerator Laboratory earlier this month as part...
A bullet fired through a block of wood will slow...
It's a familiar trope in science fiction: In enemy territory, activate your cloaking device. And real-world viruses use similar tactics to make themselves invisible to the immune system. Now scientists at Harvard Univ.'s Wyss Institute for Biologically Inspired Engineering have mimicked these viral tactics to build the first DNA nanodevices that survive the body's immune defenses.
Scientists are facing a number of barriers as they try to develop circuits that are microscopic in size, including how to reliably control the current that flows through a circuit that is the width of a single molecule. Recent work at the Univ. of Rochester may have solved this problem through the addition of a second, inert layer of molecules that can act like a plastic casing on the wires.
Of late, engineers have been paying more and more attention to nature’s efficiencies, such as the Lotus effect, which describes the way the Lotus plant uses hydrophobic surfaces to survive in muddy swamps. A researcher at Virginia Tech has developed a simpler two-step application process to create a superhydrophobic copper surface that leverages the Lotus effect.
The ability to stick objects to a wide range of surfaces such as drywall, wood, metal and glass with a single adhesive has been the elusive goal of many research teams across the world, but now a team of Univ. of Massachusetts Amherst inventors describe a new, more versatile version of their invention, Geckskin, that can adhere strongly to a wider range of surfaces, yet releases easily, like a gecko's feet.
Physicist Wei Chen at Univ. of Texas at Arlington’s Center for Security Advances Via Applied Nanotechnology was testing a copper-cysteamine complex created in his laboratory when he discovered unexplained decreases in its luminescence, or light emitting power, over a time-lapse exposure to x-rays. Further testing work revealed that the “Cu-Cy” nanoparticles, when combined with x-ray exposure, significantly slowed tumor growth in studies.
Researchers in Ireland have used a simple method for transforming flakes of graphite into defect-free graphene using commercially available tools, such as high-shear mixers. They demonstrated that the process could be scaled up to produce hundreds of liters or more, and they have partnered with Thomas Swan Ltd. to develop two new graphene-based products for the marketplace.
Scientists at Rice Univ. have created a nanoscale detector that checks for and reports on the presence of hydrogen sulfide in crude oil and natural gas while they’re still in the ground. The nanoreporter is based on nanometer-sized carbon material developed by a consortium of Rice labs led by chemist James Tour, R&D’s 2013 Scientist of the Year.
Researchers have produced a stable porous membrane that is thinner than a single nanometer. The membrane consists of two layers of graphene on which have been etched tiny pores of a precisely defined size. Extremely light and breathable, the new material could help enable a new generation of ultra-rapid filters or functional waterproof clothing.
Ever-shrinking electronic devices could get down to atomic dimensions with the help of transition metal oxides. Researchers from Cornell Univ. and Brookhaven National Laboratory have shown how to switch a particular transition metal oxide, a lanthanum nickelate (LaNiO3), from a metal to an insulator by making the material less than a nanometer thick.
Research from North Carolina State Univ. finds that impurities can hurt performance, or possibly provide benefits, in a key superconductive material that is expected to find use in a host of applications, including future particle colliders. The size of the impurities determines whether they help or hinder the material’s performance.
An international team of chemists from Italy, Germany and Poland have developed a polymer with unique optical and electrical properties. Components of this polymer change their spatial configuration depending on the electric potential applied. In turn, the polarization of transmitted light is affected. The new material could be used in a windows, polarization filters or chemical sensors.
New plasmonic metamaterials that operate at high temperatures could radically improve solar cell performance and bring advanced computer data storage technology that uses heat to record information on a magnetic disk. The materials could make it possible to harness clouds of electrons called surface plasmons to manipulate and control light.
One strategy for addressing the world’s energy crisis is to stop wasting so much energy when producing and using it, which can happen in coal-fired power plants or transportation. Nearly two-thirds of energy input is lost as waste heat. Now Northwestern Univ. scientists have discovered a surprising material that is the best in the world at converting waste heat to useful electricity.
A research group in Japan has developed a new advanced system that combines a super-resolution microscope and a deposition chamber for growing oxide thin films. With this system, they successfully observed for the first time the growing of metal-oxide thin films at an atomic level on the surface of single-crystal strontium titanate.
Although it is relatively cheap and easy to encode information in light for fiber optic transmission, storing information is most efficiently done using magnetism, which ensures information will survive for years without any additional power. But a new proposal by researchers would replace silicon used in these devices with plastic. Their solution converts magnetic information to light in a flexible plastic device.
Researchers in Pennsylvania and Texas have shown the ability to grow high quality, single-layer materials one on top of the other using chemical vapor deposition. This highly scalable technique, often used in the semiconductor industry, can produce materials with unique properties that could be applied to solar cells, ultracapacitors for energy storage, or advanced transistors for energy efficient electronics, among many other applications.
Scientists at Yale Univ. have confirmed a 50-year-old, previously untested theoretical prediction in physics and improved the energy storage time of a quantum switch by several orders of magnitude. High-quality quantum switches are essential for the development of quantum computers and the quantum Internet.
Carefully timed pairs of laser pulses at the Linac Coherent Light Source have been used to trigger superconductivity in a promising copper-oxide material and immediately take x-ray snapshots of its atomic and electronic structure as superconductivity emerged. The results of this effort have pinned down a major factor behind the appearance of superconductivity, and it hinges around “stripes” of increase electrical charge.
Counterfeiters, beware! Scientists are reporting the development of a new type of inexpensive barcode that, when added to documents or currency, could foil attempts at making forgeries. Although the tags are easy for researchers to make, they still require ingredients you can’t exactly find at the local hardware store.
Electric vehicles could travel farther and more renewable energy could be stored with lithium-sulfur batteries that use a unique powdery nanomaterial. Researchers added the powder, a kind of nanomaterial called a metal organic framework, to the battery's cathode to capture problematic polysulfides that usually cause lithium-sulfur batteries to fail after a few charges.
The chemistry of lithium-ion batteries limits how much energy they can store, and one promising solution is the lithium-sulfur battery, which can hold as much as four times more energy per mass. However, problematic polysulfides usually cause lithium-sulfur batteries to fail after a few charges. Researchers at Pacific Northwest National Laboratory, however, have developed a new powdery nanomaterial that could solve the issue.
Researchers in Finland have succeeded in creating a surface on nano-sized cellulose crystals that imitates a biological structure. The surface adsorbs viruses and disables them, preventing their spread into cells. The results could prove useful in the development of antiviral ointments and surfaces.
Researchers in California have created, for the first time, compounds made from mixtures of calcium hexaboride, strontium and barium hexaboride. They also demonstrated that these ceramic materials could be manufactured using a simple, low-cost manufacturing method known as combustion synthesis.
Nanotechnology has unlocked new pathways for targeted drug delivery, including the use of nanocarriers that can transport cargoes of small-molecule therapeutics to specific locations in the body. Researchers have recently demonstrated that processing can have significant influence on the size of nanocarriers for targeted drug delivery. It was previously assumed that once a nanocarrier is created, it maintains its size and shape anywhere.
The unique properties of engineered nanoparticles have created intense interest in their environmental behavior. Due to the increased use of nanotechnology in consumer products, industrial applications and health care technology, nanoparticles are more likely to enter the environment. For this reason, it’s not only important to know the type, size and distribution of nanoparticles, but it’s also crucial to understand their impact.
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