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The Lead

2-D quantum materials for nanoelectronics

November 21, 2014 9:10 am | by David L. Chandler, MIT News Office | News | Comments

Researchers at Massachusetts Institute of Technology say they have carried out a theoretical analysis showing that a family of 2-D materials exhibits exotic quantum properties that may enable a new type of nanoscale electronics. These materials are predicted to show a phenomenon called the quantum spin Hall (QSH) effect, and belong to a class of materials known as transition metal dichalcogenides, with layers a few atoms thick.

Collaboration points to improved nanomaterials

November 21, 2014 8:01 am | by Jim Barlow, Director of Science and Research Communications, Univ. of Oregon | News | Comments

A potential path to identify imperfections and improve the quality of nanomaterials for use in...

Argonne announces new licensing agreement with AKHAN Semiconductor

November 20, 2014 8:24 am | by Jared Sagoff, Argonne National Laboratory | News | Comments

Argonne National Laboratory has announced a new intellectual property licensing agreement with...

Spiraling light, nanoparticles and insights into life’s structure

November 20, 2014 8:12 am | by Nicole Casal Moore, Univ. of Michigan | News | Comments

As hands come in left and right versions that are mirror images of each other, so do the amino...

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Graphene/nanotube hybrid benefits flexible solar cells

November 17, 2014 3:37 pm | by Mike Williams, Rice Univ. | News | Comments

Rice Univ. scientists have invented a novel cathode that may make cheap, flexible dye-sensitized solar cells practical. The Rice laboratory of materials scientist Jun Lou created the new cathode, one of the two electrodes in batteries, from nanotubes that are seamlessly bonded to graphene and replaces the expensive and brittle platinum-based materials often used in earlier versions.

Solar-friendly form of silicon shines

November 17, 2014 11:16 am | by Carnegie Institute | News | Comments

Silicon is the second-most-abundant element in the Earth's crust. When purified, it takes on a diamond structure, which is essential to modern electronic devices—carbon is to biology as silicon is to technology. A team of Carnegie scientists has synthesized an entirely new form of silicon, one that promises even greater future applications.

Artificial muscle can “remember” movements

November 17, 2014 11:07 am | by Univ. of Cambridge | News | Comments

Researchers from the Univ. of Cambridge have developed artificial muscles which can learn and recall specific movements, the first time that motion control and memory have been combined in a synthetic material. The muscles, made from smooth plastic, could eventually be used in a applications where mimicking the movement of natural muscle would be an advantage, such as robotics, aerospace, exoskeletons and biomedical applications.

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Motion-induced quicksand

November 17, 2014 7:45 am | by Jennifer Chu, MIT News Office | News | Comments

From a mechanical perspective, granular materials are stuck between a rock and a fluid place, with behavior resembling neither a solid nor a liquid. Think of sand through an hourglass: As grains funnel through, they appear to flow like water, but once deposited, they form a relatively stable mound, much like a solid.

New form of crystalline order holds promises for thermoelectric applications

November 14, 2014 9:36 am | by Vanderbilt Univ. | News | Comments

Since the 1850s scientists have known that crystalline materials are organized into fourteen different basic lattice structures. However, a team of researchers from Vanderbilt Univ. and Oak Ridge National Laboratory now reports that it has discovered an entirely new form of crystalline order that simultaneously exhibits both crystal and polycrystalline properties, which they describe as "interlaced crystals."

Topological insulators promising for spintronics, quantum computers

November 14, 2014 7:48 am | by Emil Venere, Purdue Univ. | News | Comments

Researches have uncovered "smoking-gun" evidence to confirm the workings of an emerging class of materials that could make possible "spintronic" devices and practical quantum computers far more powerful than today's technologies. The materials are called topological insulators.

2015 R&D 100 Awards entries now open

November 13, 2014 11:27 am | by Lindsay Hock, Managing Editor | News | Comments

The editors of R&D Magazine have announced the opening of the 2015 R&D 100 Awards entry process. The R&D 100 Awards have a 50 plus year history of awarding the 100 most technologically significant products of the year. Past winners have included sophisticated testing equipment, innovative new materials, chemistry breakthroughs, biomedical products, consumer items, high-energy physics and more.

New process isolates promising material

November 13, 2014 11:11 am | by Amanda Morris, Northwestern Univ. | News | Comments

After graphene was first produced in the laboratory in 2004, thousands of laboratories began developing graphene products worldwide. Researchers were amazed by its lightweight and ultra-strong properties. Ten years later, scientists now search for other materials that have the same level of potential.

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New way to move atomically thin semiconductors for use in flexible devices

November 13, 2014 8:51 am | by Matt Shipman, News Services, North Carolina State Univ. | Videos | Comments

Researchers from North Carolina State Univ. have developed a new way to transfer thin semiconductor films, which are only one atom thick, onto arbitrary substrates, paving the way for flexible computing or photonic devices. The technique is much faster than existing methods and can perfectly transfer the atomic scale thin films from one substrate to others, without causing any cracks.

Study explains atomic action in high-temperature superconductors

November 13, 2014 7:43 am | by Andrew Gordon, SLAC National Accelerator Laboratory | News | Comments

A study at the SLAC National Accelerator Laboratory suggests for the first time how scientists might deliberately engineer superconductors that work at higher temperatures. In their report, a team of researchers explains why a thin layer of iron selenide superconducts at much higher temperatures when placed atop another material, which is called STO for its main ingredients strontium, titanium and oxygen. 

Electronic “tongue” to ensure food quality

November 12, 2014 10:35 am | by American Chemical Society | News | Comments

An electronic “tongue” could one day sample food and drinks as a quality check before they hit store shelves. Or it could someday monitor water for pollutants or test blood for signs of disease. With an eye toward these applications, scientists are reporting the development of a new, inexpensive and highly sensitive version of such a device in ACS Applied Materials & Interfaces.

Bending in search of new materials

November 11, 2014 2:15 pm | by Britt Faulstick, Drexel Univ. | News | Comments

Making a paper airplane in school used to mean trouble. Today it signals a promising discovery in materials science research that could help next-generation technology get off the ground. Researchers at Drexel Univ. and Dalian Univ. of Technology in China have chemically engineered a new, electrically conductive nanomaterial that is flexible enough to fold, but strong enough to support many times its own weight.

Good vibrations rock an insulator to go metallic

November 11, 2014 8:24 am | by Dawn Levy, Oak Ridge National Laboratory | News | Comments

For more than 50 years, scientists have debated what turns particular oxide insulators, in which electrons barely move, into metals, in which electrons flow freely. Some scientists sided with Nobel Prize–winning physicist Nevill Mott in thinking direct interactions between electrons were the key. Others believed, as did physicist Rudolf Peierls, that atomic vibrations and distortions trumped all.

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Heat transfer sets noise floor for ultra-sensitive electronics

November 11, 2014 8:10 am | by Ken Than, Caltech | News | Comments

A team of engineers and scientists has identified a source of electronic noise that could affect the functioning of instruments operating at very low temperatures, such as devices used in radio telescopes and advanced physics experiments. The findingscould have implications for the future design of transistors and other electronic components.

First look at atom-thin boundaries

November 10, 2014 10:55 am | by Morgan McCorkle, Oak Ridge National Laboratory | News | Comments

Scientists at Oak Ridge National Laboratory have made the first direct observations of a 1-D boundary separating two different, atom-thin materials, enabling studies of long-theorized phenomena at these interfaces. Theorists have predicted the existence of intriguing properties at 1-D boundaries between two crystalline components, but experimental verification has eluded researchers.

New materials yield record efficiency polymer solar cells

November 10, 2014 10:20 am | by Tracey Peake, North Carolina State Univ. | News | Comments

Researchers from North Carolina State Univ. and Hong Kong Univ. of Science and Technology have found that temperature-controlled aggregation in a family of new semiconducting polymers is the key to creating highly efficient organic solar cells that can be mass produced more cheaply. Their findings also open the door to experimentation with different chemical mixtures that comprise the active layers of the cells.

Longhorn beetle inspires ink to fight counterfeiting

November 5, 2014 9:30 am | by American Chemical Society | News | Comments

From water marks to colored threads, governments are constantly adding new features to paper money to stay one step ahead of counterfeiters. Now a longhorn beetle has inspired yet another way to foil cash fraud, as well as to produce colorful, changing billboards and art displays. In ACS Nano, researchers report a new kind of ink that mimics the beetle’s color-shifting ability in a way that would be long-lasting and difficult to copy.

Novel sodium-conducting material could improve rechargeable batteries

November 5, 2014 9:23 am | by NIST | News | Comments

Rechargeable battery manufacturers may get a jolt from research performed at NIST and several other institutions, where a team of scientists has discovered a safe, inexpensive, sodium-conducting material that significantly outperforms all others in its class. The team's discovery is a sodium-based, complex metal hydride, a material with potential as a cheaper alternative to the lithium-based conductors used in many rechargeable batteries.

Combining “Tinkertoy” materials with solar cells for increased photovoltaic efficiency

November 5, 2014 8:42 am | by Mike Janes, Sandia National Laboratories | News | Comments

Researchers at Sandia National Laboratories have received a $1.2 million award from the U.S. Dept. of Energy’s SunShot Initiative to develop a technique that they believe will significantly improve the efficiencies of photovoltaic materials and help make solar electricity cost-competitive with other sources of energy.

Engineer readies for rapid discovery of metallic glasses

November 4, 2014 9:22 am | by Rase McCry, Yale Univ. | News | Comments

Yale Univ. engineer Jan Schroers will lead a three-year, $1.2 million project intended to dramatically accelerate the pace of discovering and characterizing bulk metallic glasses (BMGs), a versatile type of pliable glass that’s stronger than steel. The grant will enable Schroers’ team to screen more than 3,000 potential BMG alloys in a week, a vast improvement over traditional methods.

New way to make batteries safer

November 3, 2014 4:51 pm | by Anne Trafton, MIT News Office | News | Comments

Every year, nearly 4,000 children go to emergency rooms after swallowing button batteries, the flat, round batteries that power toys, hearing aids, calculators and many other devices. Ingesting these batteries has severe consequences, including burns that permanently damage the esophagus, tears in the digestive tract and, in some cases, even death.

Outsmarting thermodynamics in self-assembly of nanostructures

November 3, 2014 1:56 pm | by Rachel Berkowitz, Lawrence Berkeley National Laboratory | News | Comments

If you can uniformly break the symmetry of nanorod pairs in a colloidal solution, you’re a step ahead of the game toward achieving new and exciting metamaterial properties. But traditional thermodynamic-driven colloidal assembly of these metamaterials, which are materials defined by their non-naturally-occurring properties, often result in structures with high degree of symmetries in the bulk material.

Chemists gain edge in next-gen energy

November 3, 2014 1:37 pm | by Mike Williams, Rice Univ. | News | Comments

Rice Univ. scientists who want to gain an edge in energy production and storage report they have found it in molybdenum disulfide. The Rice laboratory of chemist James Tour has turned molybdenum disulfide’s 2-D form into a nanoporous film that can catalyze the production of hydrogen or be used for energy storage.

A quantum leap in nanoparticle efficiency

October 31, 2014 12:55 pm | News | Comments

In an international study Univ. of Melbourne and NIST found that pairs of closely spaced nanoparticles made of gold can act as “optical antennas”. These antennae concentrate the light shining on them into tiny regions located in the gap between the nanoparticles. Researchers found the precise geometry of nanoparticle pairs that maximizes light concentration, resolving a hotly debated area of quantum physics.

Pilot study reveals new findings about microplastics in wastewater

October 31, 2014 10:19 am | News | Comments

Researchers in Germany have employed micro-FTIR and ATR-FTIR spectroscopy to determine precisely the type and source of microplastics found in the wastewater of a regional water association in Lower Saxony. With these infrared imaging methods, it is now possible to specifically classify plastics, such as those used in toothpaste, cosmetics, fleece jackets and packaging.

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