Science

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UMD & Army researchers discover salty solution to better, safer batteries: Greatest potential uses seen in safety-critical, automotive and grid-storage applications

A team of researchers from the University of Maryland (UMD) and the U.S. Army Research Laboratory (ARL) have devised a groundbreaking "Water-in-Salt" aqueous Lithium ion battery technology that could provide power, efficiency and longevity comparable to today's Lithium-ion batteries, but without the fire risk, poisonous chemicals and environmental hazards of current Lithium batteries.

The team of researchers, led by Chunsheng Wang, an associate professor in UMD's Department of Chemical & Biomolecular Engineering, and Kang Xu, senior research chemist at the Sensor and Electron Devices Directorate of ARL, said their work, published this week in the journal Science, demonstrates a major advance in the long history of water-based (aqueous) batteries by doubling the voltage, or power, of an aqueous battery.

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NASA Orders SpaceX Crew Mission to International Space Station

NASA took a significant step Friday toward expanding research opportunities aboard the International Space Station with its first mission order from Hawthorne, California based-company SpaceX to launch astronauts from U.S. soil.

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A new symmetry underlies the search for new materials

A new symmetry operation developed by Penn State researchers has the potential to speed up the search for new advanced materials that range from tougher steels to new types of electronic, magnetic, and thermal materials. With further developments, this technique could also impact the field of computational materials design.

"In the physical sciences, making measurements can be time consuming and so you don't want to make unnecessary ones," said Venkat Gopalan, professor of materials science and engineering. "This is true for any material property -- mechanical, electrical, optical, magnetic, thermal or any other. Knowing the symmetry group of a material can greatly reduce the number of measurements you have to make. "

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3D nanostructure of a bone made visible

Bones are made up of tiny fibres that are roughly a thousand times finer than a human hair. One major feature of these so-called collagen fibrils is that they are ordered and aligned differently depending on the part of the bone they are found in. Although this ordering is decisive for the mechanical stability of the bone, traditional computer tomography (CT) can only be used to determine the density but not the local orientation of the underlying nanostructure. Researchers at the Paul Scherrer Institute PSI have now overcome this limitation thanks to an innovative computer-based algorithm. They applied the method to measurements of a piece of bone obtained using the Swiss Light Source SLS. Their approach enabled them to determine the localised order and alignment of the collagen fibrils inside the bone in three dimensions. Aside from bone, the method can be applied to a wide variety of biological and materials science specimens.

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The bone and its nanostructure: Thanks to their newly developed algorithm, researchers at PSI succeeded in mapping the order and alignment of the tiny collagen fibrils in this entire bone fragment of roughly two and a half millimetre length.

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Application of Nanocomposite Membranes in Fuel Cells to Produce Green Energy

The application of fuel cells increases every day in various industries due to the importance of using sustainable and green energy sources.

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Plasma Focus Device Applied to Produce Zinc Oxide Nanofilms

A group of Iranian researchers used a new method to produce nanostructured films in a short period of time at room temperature.

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Ultra-short X-ray pulses could shed new light on the fastest events in physics

If you've ever been captivated by slow-motion footage on a wildlife documentary, or you've shuddered when similar technology is used to replay highlights from a boxing match, you'll know how impressive advancements in ultra-fast science can be.

Researchers from the Department of Physics at Oxford University (with colleagues at the Rutherford Appleton Laboratory and the University of Strathclyde) have demonstrated, for the first time, that it is possible to generate ultra-short x-ray pulses using existing technology - and it could open up a huge range of scientific applications.

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New nanoscopic tools to study ligand-binding of receptors

Signalling processes in organisms are governed by specific extracellular and intracellular interactions and involve hundreds of different functionally highly versatile receptors situated in cell membranes. For scientists wishing to understand signalling processes the situation is made more complex by the receptors not only being unevenly distributed and often able to bind more than one ligand but also by the same type of receptor being able to bind a ligand strongly, weakly or not at all. New methods that allow precise quantifications of such complex interactions are urgently required.

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Researchers design and patent graphene biosensors: The Moscow Institute of Physics and Technology is patenting biosensor chips based on graphene, graphene oxide and carbon nanotubes that will improve the analysis of biochemical reactions and accelerate th

Graphene is the first truly two-dimensional crystal, which was obtained experimentally and investigated regarding its unique chemical and physical properties. In 2010, two MIPT alumni, Andre Geim and Konstantin Novoselov were awarded the Nobel Prize in Physics "for ground-breaking experiments regarding the two-dimensional material graphene". There has now been a considerable increase in the number of research studies aimed at finding commercial applications for graphene and other two-dimensional materials. One of the most promising applications for graphene is thought to be biomedical technologies, which is what researchers from the Laboratory of Nanooptics and Plasmonics at the MIPT's Center of Excellence for Nanoscale Optoelectronics are currently investigating.

Label-free biosensors are relatively new in biochemical and pharmaceutical laboratories, and have made work much easier. The sensors enable researchers to detect low concentrations of biologically significant molecular substances (RNA, DNA, proteins, including antibodies and antigens, viruses and bacteria) and study their chemical properties.

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Imitating synapses of the human brain could lead to smarter electronics

Making a computer that learns and remembers like a human brain is a daunting challenge. The complex organ has 86 billion neurons and trillions of connections -- or synapses -- that can grow stronger or weaker over time. But now scientists report in the development of a first-of-its-kind synthetic synapse that mimics the plasticity of the real thing, bringing us one step closer to human-like artificial intelligence.

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Connections, or synapses, between neurons are inspiring scientists to create artificial versions that could lead to smarter electronics.