Scientist closes in on creating a superlens
Some day, you may have a microscope on your smartphone camera that’s as powerful as a scanning electron microscope. If you do, it will likely be thanks to research presently being conducted by Durdu Guney, an assistant professor of electrical and computer engineering at Michigan Technological University. He is working on creating a metamaterial-based “superlens” – a long sought-after optically-perfect lens, that could use visible light to image objects as small as 100 nanometers across.

Sourced & published by Henry Sapiecha

5. The TSA needs a Barry White theme song

It’s unlikely that John Pistole, the Transportation Security Agency’s dour chief who once warned that terrorism must “always be considered imminent,” expected such public vilification over his agency’s new airport screening procedures.

But a protest that began with a few bloggers has, since Pistole announced the pat-down or body-scan policy in a one-paragraph note on TSA.gov a few weeks ago, become something closer to public execration. TSA screeners have been twitted by Saturday Night Live, Grammy-winning musician Steve Vaus, and cartoonist Tom Tomorrow. The agency itself has been rebuked by some of the same politicians who voted unanimously to create it a decade ago.

The surprise is that, beyond exempting flight attendants and pilots, the TSA has remained unyielding and impenitent. All Pistole would tell CBS News this week is that he’ll continue asking: “How can we be better informed if we modify our screening? Then, what are the risks that we deal with?” That’s Washington-ese for “I’m Gonna Love You Just a Little More Baby.”

Photo by TSA

Read more: http://news.cnet.com/2300-1001_3-10005691-7.html?tag=mncol#ixzz17JchrIzJ

Pose Serious Threat, Scientists Warn

Science (May 22, 2009) — If you own a computer, chances are you have experienced the aftermath of a nasty virus at some point. In contrast, there have been no major outbreaks of mobile phone viral infection, despite the fact that over 80 percent of Americans now use these devices. A team headed by Albert-Laszlo Barabasi, director of the Center for Complex Network Research at Northeastern University, set out to explain why this is true.

The researchers used calling and mobility data from over six million anonymous mobile phone users to create a comprehensive picture of the threat mobile phone viruses pose to users. The results of this study, published in the May 22 issue of Science, indicate that a highly fragmented market share has effectively hindered outbreaks thus far. Further, their work predicts that viruses will pose a serious threat once a single mobile operating system’s market share grows sufficiently large. This event may not be far off, given the 150 percent annual growth rate of smart phones.

“We haven’t had a problem so far because only phones with operating systems, so-called ‘smart phones’, are susceptible to viral infection,” explained Marta Gonzalez, one of the authors of the publication. “Once a single operating system becomes common, we could potentially see outbreaks of epidemic proportion because a mobile phone virus can spread by two mechanisms: a Bluetooth virus can infect all Bluetooth-activated phones in a 10-30 meter radius, while Multimedia Messaging System (MMS) virus, like many computer viruses, spreads using the address book of the device. Not surprisingly, hybrid viruses, which can infect via both routes, pose the most significant danger.”

This study builds upon earlier research by the same group, which used mobile phone data to create a predictive model of human mobility patterns. The current work used this model to simulate Bluetooth virus infection scenarios, finding that Bluetooth viruses will eventually infect all susceptible handsets, but the rate is slow, being limited by human behavioral patterns. This characteristic suggests there should be sufficient time to deploy countermeasures such as antiviral software to prevent major Bluetooth outbreaks. In contrast, spread of MMS viruses is not restricted by human behavioral patterns, however spread of these types of viruses are constrained because the number of susceptible devices is currently much smaller.

As our world becomes increasingly connected we face unprecedented challenges. Studies such as this one, categorized as computational social science, are necessary to understand group behavior and organization, assess potential threats, and develop solutions to the issues faced by our ever-changing society.

“This is what statistical analysis of complex systems is all about: finding patterns in nature,” said Gonzalez. “This research is vital because it puts a huge amount of data into the service of science.”

Sourced & published by Henry Sapiecha

Tracking Device Fits on the Head of a

Pin: Mini-Gyroscopes to Guide

Smartphones and Medical Equipment

Science (Oct. 8, 2010) — University of Illinois chemistry professor Alexander Scheeline wants to see high school students using their cell phones in class. Not for texting or surfing the Web, but as an analytical chemistry instrument.

Scheeline developed a method using a few basic, inexpensive supplies and a digital camera to build a spectrometer, an important basic chemistry instrument. Spectrophotometry is one of the most widely used means for identifying and quantifying materials in both physical and biological sciences.

“If we want to measure the amount of protein in meat, or water in grain, or iron in blood, it’s done by spectrophotometry,” Scheeline said.

Many schools have a very limited budget for instruments and supplies, making spectrometers cost-prohibitive for science classrooms. Even when a device is available, students fail to learn the analytical chemistry principles inherent in the instrument because most commercially available devices are enclosed boxes. Students simply insert samples and record the numbers the box outputs without learning the context or thinking critically about the process.

“Science is basically about using your senses to see things — it’s just that we’ve got so much technology that now it’s all hidden,” Scheeline said.

“The student gets the impression that a measurement is something that goes on inside a box and it’s completely inaccessible, not understandable — the purview of expert engineers,” he said. “That’s not what you want them to learn. In order to get across the idea, ‘I can do it, and I can see it, and I can understand it,’ they’ve go to build the instrument themselves. ”

So Scheeline set out to build a basic spectrometer that was not only simple and inexpensive but also open so that students could see its workings and play with its components, encouraging critical-thinking and problem-solving skills. It wouldn’t have to be the most sensitive or accurate instrument — in fact, he hoped that obvious shortcomings of the device would reinforce students’ understanding of its workings.

“If you’re trying to teach someone an instrument’s limitations, it’s a lot easier to teach them when they’re blatant than when they’re subtle. Everything goes wrong out in the open,” he said.

In a spectrometer, white light shines through a sample solution. The solution absorbs certain wavelengths of light. A diffraction grating then spreads the light into its color spectrum like a prism. Analyzing that spectrum can tell chemists about the properties of the sample.

For a light source, Scheeline used a single light-emitting diode (LED) powered by a 3-volt battery, the kind used in key fobs to remotely unlock a car. Diffraction gratings and cuvettes, the small, clear repositories to hold sample solutions, are readily available from scientific supply companies for a few cents each. The entire setup cost less than $3. The limiting factor seemed to be in the light sensor, or photodetector, to capture the spectrum for analysis.

“All of a sudden this light bulb went off in my head: a photodetector that everybody already has! Almost everybody has a cell phone, and almost all phones have a camera,” Scheeline said. “I realized, if you can get the picture into the computer, it’s only software that keeps you from building a cheap spectrophotometer.”

To remove that obstacle, he wrote a software program to analyze spectra captured in JPEG photo files and made it freely accessible online, along with its source code and instructions to students and teachers for assembling and using the cell-phone spectrometer. It can be accessed through the Analytical Sciences Digital Library.

Scheeline has used his cell-phone spectrometers in several classroom settings. His first classroom trial was with students in Hanoi, Vietnam, as part of a 2009 exchange teaching program Scheeline and several other U. of I. chemistry professors participated in. Although the students had no prior instrumentation experience, they greeted the cell-phone spectrometers with enthusiasm.

In the United States, Scheeline used cell-phone spectrometers in an Atlanta high school science program in the summers of 2009 and 2010. By the end of the 45-minute class, Scheeline was delighted to find students grasping chemistry concepts that seemed to elude students in similar programs using only textbooks. For example, one student inquired about the camera’s sensitivity to light in the room and how that might affect its ability to read the spectrum.

“And I said, ‘You’ve discovered a problem inherent in all spectrometers: stray light.’ I have been struggling ever since I started teaching to get across to university students the concept of stray light and what a problem it is, and here was a high school kid who picked it right up because it was in front of her face!” Scheeline said.

Scheeline has also shared his low-cost instrument with those most likely to benefit: high school teachers. Teachers participating in the U. of I. EnLiST program, a two-week summer workshop for high school chemistry and physics teachers in Illinois, built and played with cell-phone spectrometers during the 2009 and 2010 sessions. Those teachers now bring their experience — and assembly instructions — to their classrooms.

Scheeline wrote a detailed account of the cell-phone spectrometer and its potential for chemistry education in an article published in the journal Applied Spectroscopy. He hopes that the free availability of the educational modules and software source code will inspire programmers to develop smart-phone applications so that the analyses can be performed in-phone, eliminating the need to transfer photo files to a computer and turning cell phones into invaluable classroom tools.

“The potential is here to make analytical chemistry a subject for the masses rather than something that is only done by specialists,” Scheeline said. “There’s no doubt that getting the cost of equipment down to the point where more people can afford them in the education system is a boon for everybody.”

Sourced & published by Henry Sapiecha

at Room Temperature

Science (Aug. 12, 2010) — DNA microarrays are one of the most powerful tools in molecular biology today. The devices, which can be used to probe biological samples and detect particular genes or genetic sequences, are employed in everything from forensic analysis to disease detection to drug development.

Now Paul Li and colleagues at Simon Fraser University in Burnaby, Canada have combined DNA microarrays with microfluidic devices, which are used for the precise control of liquids at the nanoscale. In an upcoming issue of the journal Biomicrofluidics, which is published by the American Institute of Physics (AIP), Li and his colleagues describe how the first combined device can be used for probing and detecting DNA.

The key to Li’s result: gold nanoparticles. Suspended in liquid and mixed with DNA, the nanometer-scale spheres of gold act as mini magnets that adhere to each of the DNA’s twin strands. When the DNA is heated, the two strands separate, and the gold nanoparticles keep them apart, which allows the single strands to be probed with other pieces of DNA that are engineered to recognize particular sequences.

Li, whose work is funded by the Natural Sciences and Engineering Research Council of Canada, is applying for a patent for his technique. He sees a host of benefits from the combination of DNA microarrays and microfluidics.

“It’s faster and requires a relatively small sample,” he says, adding in his paper that “the whole procedure is accomplished at room temperature in an hour and apparatus for high temperature… is not required”

Sourced & published by Henry Sapiecha

to Transfer Data Inside PCs

Jul 28, 2010 6:40 am

Intel on Tuesday announced it had developed a prototype interconnect that uses light to speed up data transmission inside computers at the speed of 50 gigabits per second.

Intel researchers said that the optical technology could ultimately replace the use of copper wires and electrons to carry data inside or around computers. An entire high-definition movie can be transmitted each second with the prototype, the researchers said.

The technology will also be able to carry data over longer distances than copper wires, Intel researchers said.

Intel’s chief technology officer Justin Rattner characterized the research prototype as a breakthrough in research as copper wires were reaching their limit. There is a wealth of data that needs to be moved, and transferring data at 10G bps or more over copper wires is becoming a challenge. Even if the data could be transferred over copper wires at that speed, there are distance trade-offs.

Optical interconnects solve that problem by allowing data transfers at much faster rates, and over longer distances, Rattner said on a conference call to discuss the technology.

“Photonics gives us the ability to move those mass quantities of data across the room… in a cost-effective matter,” Rattner said.

The photonics technology could potentially speed up data transfers within PCs or devices such as handhelds, where movies could be downloaded at faster rates, Rattner said.

Laser is already used in devices such as DVD players, and also for applications such as long-distance communication. Laser technology can however be expensive, and Intel wants to bring the technology down to a low-cost point where it can be integrated into everyday devices, Rattner said. The company hopes to raise the speed of the optical interconnect to reach up to 1T bps (bits per second) as it increases the number of channels to improve data transfers.

But for now, the company has demonstrated in principle that it can get the pieces together and put it together in a fab. The next step is to implement it in chips and take it to volume manufacturing. The technology could reach the mass market by the middle of the decade, and could go into PCs, servers or mobile devices.

The technology won’t be implemented at the integrated circuit level in the short term, but could replace copper wires that connect CPU to memory, for example, said Mario Paniccia, an Intel fellow. The optical interconnect will reduce latency, which could result in faster data movement and processing.

“We think it’s going to be perfectly at home in data-center applications,” Rattner said. For consumer applications, an optical interconnect would also help users to down movies to handheld devices at faster rates, Rattner said.

“Once we’re confident we have a high-volume manufacturing capability, then we’ll turn to the business question: what market opportunities are attractive to Intel?” Rattner asked.

The research prototype brings together a number of previous Intel research around devices that emit, manipulate, combine, separate and detect light. The interconnect includes a transmitter chip on a PC board that puts four optical channels on to fiber, and a receiver chip that receives the incoming light, splits the optical signals and converts the photons to electrical data.

Intel is already working on a new optical interconnect to link external storage drives, mobile devices and displays to PCs up to 100 meters away. Called Light Peak, the interconnect helps communicate data at up to 10G bps. Intel sees Light Peak as potential technology to replace USB, which is commonly used to connect storage and other devices to PCs.

Many companies, including Sun, which is now part of Oracle, and IBM have been involved in silicon photonics research.

Sourced & published by Henry Sapiecha

Video on mind controlled prosthethic arm

Atmosphere With Pinpoint Sharpness

ScienceDaily (June 28, 2010) — A sharp view of the starry sky is difficult, because the atmosphere constantly distorts the image. TU/e researcher Roger Hamelinck developed a new type of telescope mirror, which quickly corrects the image. His prototypes are required for future large telescopes, but also gives old telescopes a sharper view.

The principle of the ‘adaptive deformable mirror’ has been known some fifty odd years, but was limited especially by the technology. Thus, the actuators of earlier systems generated much heat, which caused the systems themselves to become a source of distortion. “Contrary to the old systems, this new system has an ultrathin mirror, so that very little power is needed for its deformation ,” Hamelinck explains. “In combination with the efficient, electromagnetic reluctance actuators, this reduces the heat generation of the system to a very low level. Thanks to this, no active cooling is required.” Hamelinck’s working prototype has a five-centimeter diameter. Given that the design is scalable and expandable with modules, the system is suited for very large telescopes, such as the future 42-meter-big E-ELT (European Extra Large Telescope). The E-ELT is fitted inter alia with an adaptive mirror of 2.4 meters.

Research institute TNO is so enthusiastic about Hamelinck’s work, that the institute is going to market it. Not only so for new telescopes, but also for existing ones. “It can be built into any telescope in the world,” says Ben Braam, business developer Space & Science of TNO. “When you turn on the system, the image is suddenly enhanced. As if it is putting on new spectacles at long last.” Affordable spectacles, in Braam’s opinion. “I’m thinking in terms of fifty to one hundred thousand euro. Which is relatively cheap for that world.”

Admittedly, the system does not correct for everything. Clouds continue to be a problem, for example. Consequently the best places for telescopes are still locations where one can enjoy a clear, cloudless sky most of the time. That would exclude the Netherlands, then.

Sourced & published by Henry Sapiecha

SAN DIEGO (UPI) — Increasingly sophisticated cars need to be protected from hackers who could tamper with computerized systems, U.S. scientists said.

As more cars become connected to the Internet through wireless systems, hackers could remotely sabotage the vehicles, The New York Times reported Friday.

In tests, computer security experts at the University of Washington and the University of California, San Diego, said they were able to remotely control braking, stop the engine and activate dozens of other functions, almost all of them while a car was in motion.

The researchers tested two versions of a late-model car in laboratory and field settings. The researchers did not publicly identify the manufacturer or model, but said they believed the cars were representative of the computer network systems found in many late-model cars today.

“You should expect that various entry points in the automotive environment are no more secure in the automotive environment than they are in your PC,” said Stefan Savage, a computer scientist in San Diego.

Sourced and published by Henry Sapiecha 7th June 2010