Snowflakes From William Scoresby’s Des Jüngern Tagebuch Einer Reise Auf Den Wallfischfang, (Hamburg:

NSF’s Science360 Photo of the Week

This is a close-up view of the beam created by a vortex laser.

Because the laser beam travels in a corkscrew pattern, encoding information into different vortex twists, it’s able to carry 10 times or more the amount of information than that of conventional lasers. The optics advancement could become a central component of next-generation computers designed to handle society’s growing demand for information sharing. Image credit: Natalia Litchinitser, University at Buffalo

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This supercapacitor battery can be recharged 30,000 times

A thin, flexible supercapacitor boasts high energy and power densities. Credit: University of Central Florida

Everyone and anyone with a smartphone know it is not long before your phone holds a charge for less and less time as the battery begins to degrade. But new research by scientists at the NanoScience Technology Center at the University of Central Florida (UCF), USA, could change that. The team have developed a new method for producing flexible supercapacitors that can store greater amounts of energy and can be recharged over 30,000 times without degradation. This new method could transform technology such as electric vehicles and mobile phones in the future.

‘If you were to replace the batteries with these supercapacitors, you could charge your mobile phone in a few seconds and you wouldn’t need to charge it again for over a week,’ said University of Central Florida researcher Nitin Choudhary.

The UCF team has attempted to apply newly discovered 2D materials that measure just a few atoms thick to supercapacitors. Other scientists have also tried formulations with other 2D materials including graphene, but had only limited success. The new supercapacitors are composed of millions of nanometre-thick wires coated with shells of 2D materials. The core facilitates the super-fast charging and discharging that makes supercapacitors powerful, and the 2D coating delivers the energy storage ability.

‘We developed a simple chemical synthesis approach so we can very nicely integrate the existing materials with the two-dimensional materials,’ said Yeonwoong Eric Jung, assistant professor of the study. Jung is working with UCF’s Office of Technology Transfer to patent the new process. ‘It’s not ready for commercialisation,’ Jung said. ‘But this is a proof-of-concept demonstration, and our studies show there are very high impacts for many technologies.’

(Image caption: Brain showing hallmarks of Alzheimer’s disease (plaques in blue). Credit: ZEISS Microscopy)

New imaging technique measures toxicity of proteins associated with Alzheimer’s and Parkinson’s diseases

Researchers have developed a new imaging technique that makes it possible to study why proteins associated with Alzheimer’s and Parkinson’s diseases may go from harmless to toxic. The technique uses a technology called multi-dimensional super-resolution imaging that makes it possible to observe changes in the surfaces of individual protein molecules as they clump together. The tool may allow researchers to pinpoint how proteins misfold and eventually become toxic to nerve cells in the brain, which could aid in the development of treatments for these devastating diseases.

The researchers, from the University of Cambridge, have studied how a phenomenon called hydrophobicity (lack of affinity for water) in the proteins amyloid-beta and alpha synuclein – which are associated with Alzheimer’s and Parkinson’s respectively – changes as they stick together. It had been hypothesised that there was a link between the hydrophobicity and toxicity of these proteins, but this is the first time it has been possible to image hydrophobicity at such high resolution. Details are reported in the journal Nature Communications.

“These proteins start out in a relatively harmless form, but when they clump together, something important changes,” said Dr Steven Lee from Cambridge’s Department of Chemistry, the study’s senior author. “But using conventional imaging techniques, it hasn’t been possible to see what’s going on at the molecular level.”

In neurodegenerative diseases such as Alzheimer’s and Parkinson’s, naturally-occurring proteins fold into the wrong shape and clump together into filament-like structures known as amyloid fibrils and smaller, highly toxic clusters known as oligomers which are thought to damage or kill neurons, however the exact mechanism remains unknown.

For the past two decades, researchers have been attempting to develop treatments which stop the proliferation of these clusters in the brain, but before any such treatment can be developed, there first needs to be a precise understanding of how oligomers form and why.

“There’s something special about oligomers, and we want to know what it is,” said Lee. “We’ve developed new tools that will help us answer these questions.”

When using conventional microscopy techniques, physics makes it impossible to zoom in past a certain point. Essentially, there is an innate blurriness to light, so anything below a certain size will appear as a blurry blob when viewed through an optical microscope, simply because light waves spread when they are focused on such a tiny spot. Amyloid fibrils and oligomers are smaller than this limit so it’s very difficult to directly visualise what is going on.

However, new super-resolution techniques, which are 10 to 20 times better than optical microscopes, have allowed researchers to get around these limitations and view biological and chemical processes at the nanoscale.

Lee and his colleagues have taken super-resolution techniques one step further, and are now able to not only determine the location of a molecule, but also the environmental properties of single molecules simultaneously.

Using their technique, known as sPAINT (spectrally-resolved points accumulation for imaging in nanoscale topography), the researchers used a dye molecule to map the hydrophobicity of amyloid fibrils and oligomers implicated in neurodegenerative diseases. The sPAINT technique is easy to implement, only requiring the addition of a single transmission diffraction gradient onto a super-resolution microscope. According to the researchers, the ability to map hydrophobicity at the nanoscale could be used to understand other biological processes in future.

Black phosphorus holds promise for the future of electronics

Discovered more than 100 years ago, black phosphorus was soon forgotten when there was no apparent use for it. In what may prove to be one of the great comeback stories of electrical engineering, it now stands to play a crucial role in the future of electronic and optoelectronic devices.

With a research team’s recent discovery, the material could possibly replace silicon as the primary material for electronics. The team’s research, led by Fengnian Xia, Yale’s Barton L. Weller Associate Professor in Engineering and Science, is published in the journal Nature Communications April 19.

With silicon as a semiconductor, the quest for ever-smaller electronic devices could soon reach its limit. With a thickness of just a few atomic layers, however, black phosphorus could usher in a new generation of smaller devices, flexible electronics, and faster transistors, say the researchers.

That’s due to two key properties. One is that black phosphorus has a higher mobility than silicon—that is, the speed at which it can carry an electrical charge. The other is that it has a bandgap, which gives a material the ability to act as a switch; it can turn on and off in the presence of an electric field and act as a semiconductor. Graphene, another material that has generated great interest in recent years, has a very high mobility, but it has no bandgap.

Read more.

On this day in 1996, then-World Chess Champion Garry Kasparov makes his first move in the sixth game against Deep Blue, IBM’s supercomputer. Kasparov emerged the victor, winning three games, drawing in two, and losing one.

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Major Research Instrumentation Program

Credit: Photo by Lance Long; courtesy Electronic Visualization Laboratory, University of Illinois at Chicago

The Major Research Instrumentation program has helped to fund pieces of research equipment ranging from scanning probe microscopes, which have helped to visualize and characterize nano-scale biological tools, to nuclear magnetic resonance (NMR) spectrometers, which allow chemists to identify the individual molecules they make. Not only does this instrumentation help scientists advance their own research, it’s also used to train the next generation of scientists. For example, an X-ray diffractometer at Utah State University allowed Joan Hevel and Sean Johnson to teach four high school students in their lab about protein crystallization. Learn more.

Dutch trains now all powered by wind energy

All Dutch trains have become 100% powered by electricity generated by wind energy, the national railway company NS has said, making it a world’s first.

One windmill running for an hour can power a train for 120 miles, the companies said. Dutch electricity company Eneco won a tender offered by NS two years ago and the two companies signed a 10-year deal setting January 2018 as the date by which all NS trains should run on wind energy. ‘We in fact reached our goal a year earlier than planned,” said NS spokesman Ton Boon, adding that an increase in the number of wind farms across the country and off the coast of the Netherlands had helped NS achieve its aim.

They hope to reduce the energy used per passenger by a further 35% by 2020 compared with 2005.