Saturday, November 28, 2015

Scientists have discovered a material that could create quantum optical computers

Scientists have discovered a material that could create quantum optical computers
Just when you thought data couldn't get any faster.

When people talk about the next-generation of computers, they're usually referring to one of two things: quantum computers – devices that will have exponentially greater processing power thanks to the addition of quantum superposition to the binary code – and optical computers, which will beam data at the speed of light without generating all the heat and wasted energy of traditional electronic computers.
Both of those have the power to revolutionise computing as we know it, and now scientists at the University of Technology, Sydney have discovered a material that has the potential to combine both of those abilities in one ridiculously powerful computer of the future. Just hold on for a second while we freak out over here.
The material is layered hexagonal boron nitride, which is a bit of a mouthful, but all you really need to know about it is that it's only one atom thick – just like graphene – and it has the ability to emit a single pulse of quantum light on demand at room temperature, making it ideal to help build a quantum optical computer chip.
Until now, room-temperature quantum emitters had only worked in a chunky, 3D material such as diamonds, which were never going to be easy to integrate onto computer chips. 
"This material – layered hexagonal boron nitride (boron and nitrogen atoms that are arranged in a honeycomb structure) – is rather unique," said one of the researchers, Mike Ford. "It is atomically thin and is traditionally used as a lubricant; however upon careful processing we discovered that it can emit quantised pulses of light – single photons that can carry information.
"That’s important because one of the big goals is to make optical computer chips that can operate based on light rather than electrons, therefore operating much faster with less heat generation," he added.
So how does a pulse of light work with quantum computing? In a traditional computer system, photons – particles of light – can be used to store information by being in either vertical or horizontal polarisation.
But they can also be turned into quantum bits (or qubits) by being put into superposition – a unique quantum state where they're in both vertical and horizontal polarisation at the same time. That's a big deal for security, and also processing power.
"You can create very secure communication systems using single photons,"explained team member Igor Aharonovich. "Each photon can be employed as a qubit (quantum bit, similarly to standard electronic bits), but because one cannot eavesdrop on single photons, the information is secure."
Best of all, the material just happens to also be cheap and easy to make, which means that it could be easily scaled up.
"This material is very easy to fabricate," said PhD student Trong Toan Tran. "It’s a much more viable option because it can be used at room temperature; it’s cheap, sustainable and is available in large quantities."
"Ultimately we want to build a 'plug and play' device that can generate single photons on demand, which will be used as a first prototype source for scalable quantum technologies that will pave the way to quantum computing with hexagonal boron nitride," he added.
The research has been published in Nature NanotechnologyNow all we really want to know is whether the new material would also work with Li-Fi. If that's the case, our future is pretty much set.

Tuesday, November 24, 2015

Li-Fi has just been tested in the real world, and it's 100 times faster than Wi-Fi

Li-Fi has just been tested in the real world, and it's 100 times faster than Wi-Fi


Sorry, Wi-Fi. We had some good times together. 







Expect to hear a whole lot more about Li-Fi - a wireless technology that transmits high-speed data using visible light communication (VLC) - in the coming months. With scientists achieving speeds of 224 gigabits per second in the lab using Li-Fi earlier this year, the potential for this technology to change everything about the way we use the Internet is huge.
And now, scientists have taken Li-Fi out of the lab for the first time, trialling it in offices and industrial environments in Tallinn, Estonia, reporting that they can achieve data transmission at 1 GB per second - that's 100 times faster than current average Wi-Fi speeds.
"We are doing a few pilot projects within different industries where we can utilise the VLC (visible light communication) technology," Deepak Solanki, CEO of Estonian tech company, Velmenni, told IBTimes UK
"Currently we have designed a smart lighting solution for an industrial environment where the data communication is done through light. We are also doing a pilot project with a private client where we are setting up a Li-Fi network to access the Internet in their office space.”
Li-Fi was invented by Harald Haas from the University of Edinburgh, Scotlandback in 2011, when he demonstrated for the first time that by flickering the light from a single LED, he could transmit far more data than a cellular tower. Think back to that lab-based record of 224 gigabits per second - that's 18 movies of 1.5 GB each being downloaded every single second.
The technology uses Visible Light Communication (VLC), a medium that uses visible light between 400 and 800 terahertz (THz). It works basically like an incredibly advanced form of Morse code - just like switching a torch on and off according to a certain pattern can relay a secret message, flicking an LED on and off at extreme speeds can be used to write and transmit things in binary code. 
And while you might be worried about how all that flickering in an office environment would drive you crazy, don’t worry - we’re talking LEDs that can be switched on and off at speeds imperceptible to the naked eye. 
lifi environment
The benefits of Li-Fi over Wi-Fi, other than potentially much faster speeds, is that because light cannot pass through walls, it makes it a whole lot more secure, and as Anthony Cuthbertson points out at IBTimes UK, this also means there's less interference between devices.
While Cuthbertson says Li-Fi will probably not completely replace Wi-Fi in the coming decades, the two technologies could be used together to achieve more efficient and secure networks.
Our homes, offices, and industry buildings have already been fitted with infrastructure to provide Wi-Fi, and ripping all of this out to replace it with Li-Fi technology isn’t particularly feasible, so the idea is to retrofit the devices we have right now to work with Li-Fi technology.
Research teams around the world are working on just that. Li-Fi expertsreported for the The Conversation last month that Haas and his team have launched PureLiFi, a company that offers a plug-and-play application for secure wireless Internet access with a capacity of 11.5 MB per second, which is comparable to first generation Wi-Fi. And French tech company Oledcomm is in the process of installing its own Li-Fi technology in local hospitals.
If applications like these and the Velmenni trial in Estonia prove successful, we could achieve the dream outlined by Haas in his 2011 TED talk below - everyone gaining access to the Internet via LED light bulbs in their home.
"All we need to do is fit a small microchip to every potential illumination device and this would then combine two basic functionalities: illumination and wireless data transmission," Haas said. "In the future we will not only have 14 billion light bulbs, we may have 14 billion Li-Fis deployed worldwide for a cleaner, greener, and even brighter future."

Sunday, July 5, 2015

China says its bullet trains will soon be able to reach 500 km/h

China says its bullet trains will soon be able to reach 500 km/h
The new technology is expected to be rolled out by 2018.





China has announced that's it's developed new technology that will help its bullet trains reach an ultra-fast 500 km/h.
That isn't quite as fast as Japan's Maglev trains, which hit record-breaking speeds of 590 km/h earlier this year, but it's more than twice the top speed of most trains in the US, and more than three times that of Australia's rail network. And in a win for the local economy, the technology is all its own.
"Now we have our own permanent magnet synchronous traction system with full intellectual property rights, marking a new chapter in China's high-speed railways," Ding Rongjun, head of the Zhuzhou Institute in the country's Hunan province, where the technology was developed, told China Daily
So what's a permanent magnet synchronous traction system? It's basically a motor that uses permanent magnets rather than a magnetic field created by windings of the rotor to propel the train forward. That means the new 690-kilowatt traction system has significantly fewer parts and is lighter and more efficient, allowing China's already-speedy bullet trains to go 50 percent faster.
But unlike the Maglev system, the train remains in contact with the track, and so is still subject to the effects of friction. 
The new traction technology was developed by CRRC Corp, the country's largest train maker, and has been in development for close to 12 years, according to China Daily.
In 2011, the team installed a lower power 190-kilowatt version of the new traction system on trains running on Subway Line 2 in Shenyan, in the Liaoning province. As of May 2015, the equipment had operated without any malfunctions for 70,000 kilometres of train travel, Want China Times reports.
It started trialling the 690-kilowatt system - which Rongjun claims will be capable of 500 km/h - in selected bullet trains in October last year. If all goes to schedule, the system will soon enter mass production and will be rolled out across the country by 2018.
Today's bullet trains are mostly powered by alternating current asynchronous motors, a traction system that was developed back in the '70s. Jia Limin from Beijing Jiaotong University, and head of China's high-speed railway innovation program,told China Daily that the upgrade will reduce electrical configuration and could also reduce electrical consumption.
"The new system has fewer parts than the current traction apparatus, so it is more reliable and efficient," he explained.
We'll wait until the new train speeds are verified before we get too excited, but we're always fans of anything that makes train travel faster and more efficient. And while 500 km/h is a far cry from the 1,200 km/h top speed promised by Elon Musk's hypothetical hyperloop system, it would still take us from Los Angeles to San Francisco in just over an hour, which would be pretty damn cool. Bring it on!


Watch: The awesome chemistry of fireworks

Watch: The awesome chemistry of fireworks
How to make sparkles.







Fireworks were invented in China thousands of years ago, and over the centuries they have been perfected to create wonderful light displays that are seen on many holidays, including the 4th of July, Chinese New Year, and New Year' s Eve celebrations around the world. How are they made?
Gunpowder is the key ingredient, but as adjunct professor of chemistry John Conkling from Washington College in the US explains in this video, without chemistry, you wouldn’t have burning mixtures and without these you simply can’t have fireworks. 
Titanium gives a sparkling effect; strontium salts and lithium carbonate makes red; barium compounds are used to make green; sodium nitrate is needed to add yellow hues; magnesium or aluminium produce white light; blue is made out of copper compounds; and purple is a mix or strontium and copper.
Watch the video above to learn more about the chemistry of fireworks.
And, if you’ve ever wondered which is the largest single firework explosion in the world, just remember that every September the glorious 'Yonshakudama Shell' illuminates the sky of Ojiya City in Japan. Yonshakudama has a diameter of 1.2 metres and weighs a massive 420 kilograms. 

The Science of Beer

 The Science of Beer
Discovered around 8,000 years ago in ancient Egypt, beer is humanity's first biotechnology venture. RiAus's A Week in Science is here to tell you why it's more nutritious than wine, and what the ancient Greeks and Romans did with it (hint: they didn't drink it).

 
The world's first beer brewers came from ancient Egypt and the southern Mesopotamian civilisation of Sumer in modern-day Iraq some 8,000 years ago. They invented the crisp, amber drink by mixing bread, germinated grain and water in ceramic jars, and the yeast inside the bread fermented the sugars in the grain, producing alcohol and, you guessed it, beer!
Funnily enough, almost everyone drank beer during this time, because it was high in carbohydrates and protein, but was also safer to drink than the contaminated water. It was basically the ultimate food and drink source.
Today you might see thousands of different brands of beer around the world, boasting all sorts of weird and wonderful flavours, but there are really only two types of beer - ales and lagers. The difference comes from the type of yeast used in the manufacturing process. Ales use a 'top-fermenting' yeast, which operates at higher temperatures so that the fermentation can produce not only alcohol, but also various aroma molecules that give the drink its fruity and floral flavours. Lagers, on the other hand, use 'bottom-fermenting' yeast, which produce no extra aroma molecules, so the beer is nothing but crisp and clear.

Researchers have worked out how to make jet diesel from sugarcane


Researchers have worked out how to make jet diesel from sugarcane
The fuel could make air travel greener and won't compete with food crops, researchers claim.



With eight million of us flying every day and rising, the environmental cost of air travel is a substantial one - in 2012, it was estimated that 2 percent of all carbon emissions were down to aeroplane operations, and that figure is expected to increase in the near future. Against that backdrop, scientists across the world are working on alternative fuels to make air travel a greener form of transport.
A team of researchers from the University of California, Berkeley in the US have come across a novel alternative fuel: sugarcane biomass and waste. The academics say that producing jet diesel from this natural source would substantially reduce greenhouse gas emissions. What's more, because the sugarcane can be grown on marginal, low-yield land, it wouldn't have to replace existing food crops.
"We've identified a new route of chemistry with its source from sugars in sugarcane plus some of the so-called waste material called bagasse," co-author Alexis Bell told Mark Kinver from the BBC. "We show in this paper how we can put these components together to make jet diesel and lubricants."
The process works by using a hot water treatment to remove sugar from the sugarcane, before renewable catalysts (tiny amounts of magnesium oxide and niobium pentoxide) are used to transform the waste into fuel.
Up to this point scientists have struggled to find a viable biofuel to meet the demands of today's high-powered aircraft - there are strict regulations in place in terms of weight, density, lubricity and performance in low temperatures that airlines insist on to keep efficiency at the required levels. But Bell says his new sugarcane fuel meets all of the necessary criteria.
The first commercial flight partly powered by biofuel was back in February 2008, but interest in greener fuel has waned over concerns that the production of the necessary crops would increase strain on worldwide food production. The sugarcane fuel developed by Bell and his colleagues avoids that problem.
"If, for example, we were to use sugar beet instead of sugarcane then there would be a potential conflict over fuel versus food," he says. "By using sugarcane, particularly in Brazil, on land that is not used for agriculture, we escape that conundrum." Bell added that any clearing of ground for sugarcane production would have to be environmentally sound to make the potential benefits worthwhile.
The research, published in the Proceedings of the National Academy of Sciences, has been sponsored by BP and the scientists are now seeking a patent for the innovations they've made. The process may well be used to create lubricants first of all, before becoming part of cleaner jet fuel mixtures.

Thursday, July 2, 2015

Engineers have boosted fibre optic capacity nearly 20 times

Engineers have boosted fibre optic capacity nearly 20 times
Unbreak the Internet.


 
As humanity sends exponentially more data online, experts have voiced concerns that the world could soon run out of fibre optic capacity. Even though connection speeds are slowly creeping up in certain parts of the world, the worry is that we're eventually we're going to hit a limit of how fast fibre optic cables, AKA the "backbone of the Internet", can actually physically carry all that data.
But engineers from the University of California, San Diego in the US have smashed the current limit, by deciphering information that had been sent through fibre optic cables across a record-breaking distance of 12,000 km, without having to regenerate the signal. That means their signal was nearly 20 times stronger than our cables can currently handle.
Right now, when we send information over a certain distance, we need to use devices called 'repeaters' along the cable to convert the data into an electrical signal. This slows the system down and limits how much information can be sent, but it's necessary because our optical signals just can't handle that much power without being distorted an unrecognisable amount.
"Today’s fibre optic systems are a little like quicksand," lead researcher Nikola Alicexplains in a press release. "With quicksand, the more you struggle, the faster you sink. With fibre optics, after a certain point, the more power you add to the signal, the more distortion you get, in effect preventing a longer reach."
"Our approach removes this power limit, which in turn extends how far signals can travel in optical fibre without needing a repeater,” he adds.
To avoid this distortion, which is known as 'crosstalk', the team first had to study it closely and map the interaction that occurred between the various channels of fibre optic cables. "Crosstalk between communication channels within a fibre optic cable obeys fixed physical laws. It’s not random," says Alic. And this means they could learn how to predict it. 
His team then created a 'frequency comb' - a device that predicts and reverses crosstalk - which allowed them to send 20 times stronger signals through fibre optic cables, without the need for regenerators.
Alic compares it to a conductor tuning up an orchestra at the start of a performance: by synchronising the starting point of the signals using the frequency comb, the team can ensure that they are deciphered without distortion on the other end, even if they've been blasted over 12,000 km.
The researchers now need to work on getting these frequency combs integrated into existing fibre optic cables. But once they do, they not only have the potential to make fibre optic cables more efficient and remove the 'speed limit' currently set on the Internet, but it could also greatly reduce the cost. 
Now if only we could work out how to get fibre into more homes around the world so we can take advantage of this awesome research.