|  Author | Topic: New Millenium Technology VIII (Read 7,448 times) |
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|  | Re: New Millenium Technology VIII
« Reply #135 on May 15, 2012, 9:43am » | |
In Metallic Glasses, Researchers Find a Few New Atomic Structures
ScienceDaily (May 11, 2012) — Drawing on powerful computational tools and a state-of-the-art scanning transmission electron microscope, a team of University of Wisconsin-Madison and Iowa State University materials science and engineering researchers has discovered a new nanometer-scale atomic structure in solid metallic materials known as metallic glasses.
Published May 11 in the journal Physical Review Letters, the findings fill a gap in researchers' understanding of this atomic structure. This understanding ultimately could help manufacturers fine-tune such properties of metallic glasses as ductility, the ability to change shape under force without breaking, and formability, the ability to form a glass without crystalizing.
Glasses include all solid materials that have a non-crystalline atomic structure: They lack a regular geometric arrangement of atoms over long distances. "The fundamental nature of a glass structure is that the organization of the atoms is disordered-jumbled up like differently sized marbles in a jar, rather than eggs in an egg carton," says Paul Voyles, a UW-Madison associate professor of materials science and engineering and principal investigator on the research.
Researchers widely believe that atoms in metallic glasses are arranged only as pentagons in an order known as five-fold rotational symmetry. However, in studies of a zirconium-copper-aluminum metallic glass, Voyles' team found there are clusters of squares and hexagons-in addition to clusters of pentagons, some of which form chains-all located within the space of just a few nanometers. "One or two nanometers is a group of about 50 atoms-and it's how those 50 atoms are arranged with respect to one another that's the new and interesting part," he says.
Measuring the atomic structure of glass at this scale has been extremely difficult. Researchers know that, at a few tenths of a nanometer, atoms in metallic glasses have the same distances between them as they do in crystals. They also know that at long distances-hundreds of nanometers-there's no order left. "But what happens in between, at this 'magic' length of one to three nanometers, is very hard to measure experimentally and is essentially unexplored in experiments and simulations," says Voyles.
An expert in electron microscopy, Voyles used a powerful, state-of-the-art scanning transmission electron microscope at UW-Madison as his window into this nanometer-scale atomic structure. The microscope can generate an electron probe beam two nanometers in diameter-the ideal size for examining atoms on a length scale of one to three nanometers. "And that, fundamentally, is what makes the experiments work and gives us access to this information that's otherwise very difficult to obtain," he says. "We can match our experimental probe in size right to the size of what we want to measure."
Voyles and his team coupled the experimental data from the microscope with state-of-the-art computational methods to conduct simulations that accurately reflect the experiments. "It's the combination of those two things that gives us this new insight," he says. "We can look at the results and abstract general principles about rotational symmetry and nanoscale clustering."
There were several clues in the properties of some metallic glasses that these competing geometric structures might exist. Those arise from the interrelationships of structure, processing and properties, says Voyles. "If we understand how the structure controls, for example, glass-forming ability or the ability to change shape on bending or pulling, and we understand how different elements participate in these different kinds of structures, that gives us a handle on controlling properties by adjusting the composition or adjusting the rate at which the material was cooled or heated to change the structure in some useful way," he says.
One of the unique characteristics of glasses is their ability to transition continuously from a solid to a liquid state. While other materials, when heated, are partly melted and partly solid, glasses as a whole become increasingly malleable.
While manufacturers now apply metallic glasses primarily in electrical transformer cores, their special forming capabilities may enable manufacturers to make very small, intricate parts. "Unlike conventional metallic alloys, metallic glasses can be molded like plastic-so they can be pushed or sucked or blown into very complicated shapes without any loss of material or machining," says Voyles.
Those manufacturing methods hold true even at the micro or nanoscale, so it's possible to make, for example, forests of nanowires or the world's smallest geared motor. "Five or 10 years from now, there may be more commercial applications driven by those kinds of things than there are now," he says.
For Voyles and his team, the next step will be to calculate the properties of the most realistic structural models of metallic glass they have developed to learn how those properties relate to the structure.
Other authors on the Physical Review Letters paper include lead author Jinwoo Hwang, Z.H. Melgarejo and Don Stone of UW-Madison, and Y.E. Kalay, I. Kalay and M.J. Kramer of Iowa State University.
Story Source:
The above story is reprinted from materials provided by University of Wisconsin-Madison. The original article was written by Renee Meiller.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
Journal Reference:
Jinwoo Hwang, Z. Melgarejo, Y. Kalay, I. Kalay, M. Kramer, D. Stone, P. Voyles. Nanoscale Structure and Structural Relaxation in Zr_{50}Cu_{45}Al_{5} Bulk Metallic Glass. Physical Review Letters, 2012; 108 (19) DOI: 10.1103/PhysRevLett.108.195505
http://www.sciencedaily.com/releases/2012/05/120511133737.htm
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"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
Arthur Schopenhauer, Philosopher, 1788-1860
"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
John F. Kennedy |
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Big Bunny
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| | Re: New Millenium Technology VIII
« Reply #136 on May 15, 2012, 9:46am » | |
You Can't Play Nano-Billiards On a Bumpy Table
ScienceDaily (May 14, 2012) — There's nothing worse than a shonky pool table with an unseen groove or bump that sends your shot off course: a new study has found that the same goes at the nano-scale, where the "billiard balls" are tiny electrons moving across a "table" made of the semiconductor gallium arsenide.
These tiny billiard tables are of interest towards the development of future computing technologies. In a research paper titled "The Impact of Small-Angle Scattering on Ballistic Transport in Quantum Dots," an international team of physicists has shown that in this game of "semiconductor billiards," small bumps have an unexpectedly large effect on the paths that electrons follow.
Better still, the team has come up with a major redesign that allows these bumps to be ironed out. The study, led by researchers from the UNSW School of Physics, is published in the journal Physical Review Letters.
The team included colleagues, from the University of Oregon (US), Niels Bohr Institute (Denmark) and Cambridge University (UK).
"Scaled down a million-fold from the local bar variety, these microscopic pool tables are cooled to just above absolute zero to study fundamental science, for example, how classical chaos theory works in the quantum mechanical limit, as well as questions with useful application, such as how the wave-like nature of the electron affects how transistors work," says team member Associate Professor Adam Micolich. "In doing this, impurities and defects in the semiconductor present a serious challenge."
Ultra-clean materials are used to eliminate impurities causing backscattering (akin to leaving a glass on the billiard table) but until now has been no way to avoid the ionized silicon atoms that supply the electrons.
"Their electrostatic effect is more subtle, essentially warping the table's surface." explains Micolich.
Earlier studies assumed this warping was negligible, with the electron paths determined only by the billiard table's shape (e.g. square, circular, stadium-shaped).
"We found that we can 'reconfigure' the warping by warming the table up and cooling it down again, with the electron paths changing radically in response," says Professor Richard Taylor from the University of Oregon. "This shows that the warping is much more important than expected."
Using a new billiard design developed during PhD work at UNSW by lead author Dr Andrew See, the silicon dopants are removed, eliminating the associated warping, and enabling the electron paths to stay the same each time they cool the device down for study.
"These undoped billiard devices pinpoint the silicon dopants as the cause of the warping. The level of improvement obtained by removing the silicon was unexpected, earlier work on much larger devices suggested that we wouldn't see this level of improvement.
But at the nanoscale, the dopant atoms really do make a really big difference," says Micolich, "Ultimately, our work provides important insight into how to make better nanoscale electronic devices, ones where the properties are both more predictable, and more consistent each time we use them."
Story Source:
The above story is reprinted from materials provided by University of New South Wales.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
Journal Reference:
A. See, I. Pilgrim, B. Scannell, R. Montgomery, O. Klochan, A. Burke, M. Aagesen, P. Lindelof, I. Farrer, D. Ritchie, R. Taylor, A. Hamilton, A. Micolich. Impact of Small-Angle Scattering on Ballistic Transport in Quantum Dots. Physical Review Letters, 2012; 108 (19) DOI: 10.1103/PhysRevLett.108.196807
http://www.sciencedaily.com/releases/2012/05/120514104957.htm
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"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
Arthur Schopenhauer, Philosopher, 1788-1860
"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
John F. Kennedy |
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Big Bunny
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| | Re: New Millenium Technology VIII
« Reply #137 on May 15, 2012, 9:53am » | |
New Ultra-Thin Electronic Films Have Greater Capacity
![[image]](http://imageshack.us/a/img171/355/120511122059.jpg "[image]")
Atomic force microscopy image of a glycopolymer nano-organized into sugar cylinders in a silicon containing polystyrene matrix. (Credit: © CERMAV (CNRS))
ScienceDaily (May 11, 2012) — The development of a new combination of polymers associating sugars with oil-based macromolecules makes it possible to design ultra-thin films capable of self-organization with a 5-nanometer resolution. This opens up new horizons for increasing the capacity of hard discs and the speed of microprocessors.
The result of a French-American collaboration spearheaded by the Centre de Recherches sur les Macromolécules Végétales (CNRS), this work has led to the filing of two patents. It is published in the journal ACS Nano. This new class of thin films based on hybrid copolymers could give rise to numerous applications in flexible electronics, in areas as diverse as nanolithography, biosensors and photovoltaic cells.
Before new generations of microprocessors can be devised, an evolution in lithography, the technique used for printing electronic circuits, is indispensable. Until now, the thin films used in electronic circuits have been designed from synthetic polymers exclusively derived from petroleum. However, these thin films have limitations: their minimum structural resolution is around 20 nanometers and cannot be reduced further by combining petroleum-derived polymers. This limit has been one of the main obstacles to the development of new generations of very-high-resolution flexible electronic devices.
Why was there such a limit? Because of the low incompatibility between the two blocks of polymers, both derived from oil. For that reason, the team headed by Redouane Borsali, CNRS senior researcher at the Centre de Recherches sur les Macromolécules Végétales (CERMAV), came up with a hybrid material: this new class of thin films combines sugar-based and petroleum-derived (silicon containing polystyrene) polymers with widely different physical/chemical characteristics. This copolymer(1), formed of highly incompatible elementary building blocks, is similar to an oil bubble attached to a small water bubble. The researchers have shown that this type of structure is capable of organizing itself into sugar cylinders within a petroleum-based polymer lattice, each structure having a size of 5 nanometers, i.e. much smaller than the resolution of "old" copolymers, exclusively composed of petroleum derivatives. In addition, this new generation of material is made from an abundant, renewable and biodegradable resource: sugar.
Achieving this performance makes it possible to envisage numerous applications in flexible electronics: miniaturization of circuit lithography, six-fold increase in information storage capacity (flash memories -- USB keys -- no longer limited to 1 Tbit of data but 6 Tbit), enhanced performance of photovoltaic cells, biosensors, etc. The researchers are now seeking to improve control of these nano-glycofilms' large-scale organization and design in different self-organized structures.
These results follow prior work carried out by CERMAV within the framework of the Grenoble RTRA (Thematic Network of Advanced Research) "Nanosciences at the limits of nanolectronics."
Story Source:
The above story is reprinted from materials provided by CNRS (Délégation Paris Michel-Ange), via AlphaGalileo.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
Journal Reference:
Julia D. Cushen, Issei Otsuka, Christopher M. Bates, Sami Halila, Sébastien Fort, Cyrille Rochas, Jeffrey A. Easley, Erica L. Rausch, Anthony Thio, Redouane Borsali, C. Grant Willson, Christopher J. Ellison. Oligosaccharide/Silicon-Containing Block Copolymers with 5 nm Features for Lithographic Applications. ACS Nano, 2012; 6 (4): 3424 DOI: 10.1021/nn300459r
http://www.sciencedaily.com/releases/2012/05/120511122059.htm
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"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
Arthur Schopenhauer, Philosopher, 1788-1860
"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
John F. Kennedy |
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Big Bunny
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| | Re: New Millenium Technology VIII
« Reply #138 on May 15, 2012, 9:55am » | |
Real Smart: Protective Clothing With Built-In A/C
![[image]](http://imageshack.us/a/img825/8149/120514104420.jpg "[image]")
The ballistic vest to be worn under the uniform shirt with integrated "air conditioning unit", for use by police personnel, for example. (Credit: Image courtesy of Empa)
ScienceDaily (May 14, 2012) — In order to test the new "smart" protective vest, an experimenter wearing one has jogged several kilometers on the treadmill in a climate-controlled chamber at Empa. During the jog he lost 544 grams in weight through sweating -- but thanks to the vest's integrated cooling system this was still 191 grams less than if he had been wearing a conventional garment.
Functional sportswear is taken for granted nowadays. It is quite unexceptional for a sports jacket, for instance, to be both waterproof and breathable. In the case of working clothes, the functionality is mostly restricted to personal protection against fire, sharp objects, chemicals and so on, with wearer comfort (mostly) not being significance top priority. Bullet-proof vests made of Kevlar, as their name suggests, hold off bullets but they are also impenetrable for water vapor. Thus police personnel who must wear such gear under their uniforms sweat profusely when the weather is warm. A situation that is merely uncomfortable when working in the office negatively affects the physical performance of police officers on duty.
Empa has now, together with its industrial partners, developed a "smart" protective vest with an integrated cooling system based on the Coolpad technology, originally designed for use in cooling garments for medical applications. The Coolpads built into the vest are filled with water, which is allowed to evaporate through the membrane, cooling down its surroundings. A mini fan blows air though a fabric spacer behind the pad, providing further cooling.
Integrating such an A/C into a garment proved to be quite tricky. It required a novel fabric spacer, which was stable under pressure yet also flexible and soft to the touch, and which offered very little resistance to air flow. A suitable spacer was developed together with Swiss textile manufacturer Eschler. Likewise, there were no fans on the market, which were small enough to be built into the vest; so Empa engineers designed a miniaturized version themselves. Two units including batteries and control electronics now provide the cooling air circulation in the vest. Similarly, the cool pads used till then proved unsatisfactory -- since in the protective vest they were mechanically quite stressed they frequently leaked water. A new technique for welding the ultra-thin pad membranes using diode lasers proved to be much more reliable than the conventional method, with the seam remaining soft and flexible. In addition the Empa specialists were able to increase the evaporation rate and therefore the cooling ability.
But that wasn't all. In order to simplify refilling the cool pads with water they developed a portable filling station that can be attached to the vest with a quick-release fastener. During the same "pit stop," the mini fans can be exchanged for those with freshly charged batteries. Then the vest is ready once again for three to four hours of duty.
Comparative measurements show that the new vest is significantly lighter and also cools much better than systems currently on the market. And in practical use, too, the vest has proven its worth. Staff of the Zürich City police force tested the vest over several warm summer days and gave the new innovation the thumbs up. The first small series of the novel under-uniform protective vest will be produced in the near future by project partner Unico swiss tex GmbH. The "smart" cooling technology is, however, also suitable for protective suits worn over normal clothing, uniform jackets, camouflage suits and even for rucksacks. Developments along these lines are already in progress.
Story Source:
The above story is reprinted from materials provided by Empa, via AlphaGalileo.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
http://www.sciencedaily.com/releases/2012/05/120514104420.htm
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"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
Arthur Schopenhauer, Philosopher, 1788-1860
"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
John F. Kennedy |
|
Big Bunny
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| | Re: New Millenium Technology VIII
« Reply #139 on Jun 4, 2012, 11:25am » | |
Seriously bad taste:
Meet Orville: The flying, dead, stuffed, cat
news.com.au
June 04, 2012 1:30PM
![[image]](http://imageshack.us/a/img844/9383/107777orvillecopter.jpg "[image]")
Orville, the flying helicopter cat by artist Bert Jansen is displayed at the KunstRai in Amsterdam. Picture: AAP
Video link: http://youtu.be/6c4nZJ4ryFE
YES. This cat's name is Orville. As in, Orville Wright, one half of the famous Wright brothers.
But that's where the Wright ends, because the rest of this story is just so wrong.
You see, Orville the cat is dead. He was unfortunately run over by a car.
Yet instead of being peacefully laid to rest, Orville became the centrepiece in his owner's art project.
Dutchman Bart Jansen contrived the "half cat, half machine" artistic tribute you see before you: a flying, dead, cat, radio-controlled, helicopter.
The resulting Orvillecopter has been put on display at the Kunstrai art festival in Amsterdam. So, if, like, taxonomy and aviation are your thing, make sure you get along.
Jansen says, in describing the Orvillecopter: "after a period of mourning he received his propellers posthumously".
"Oh how he loved birds. He will receive more powerful engines and larger props for his birthday. So this hopping will soon change into steady flight."
That's sweet.
Read more: http://www.news.com.au/travel/news/meet-....#ixzz1wqHXo9 Vo
|
"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
Arthur Schopenhauer, Philosopher, 1788-1860
"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
John F. Kennedy |
|
Big Bunny
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Posts: 50,822
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| | Re: New Millenium Technology VIII
« Reply #140 on Jun 9, 2012, 9:51am » | |
Cyber warfare: Fear of system failure
![[image]](http://imageshack.us/a/img576/5760/p00tmbhw.jpg "[image]")
(Copyright: Thinkstock)
The discovery of Flame and Stuxnet leaves security experts concerned there are similar malicious software attacks already underway that their systems cannot detect.
It’s rare to hear someone admit to failure. Even rarer to admit that their company and the entire industry it represents is guilty of a “spectacular failure”. But that is just what Mikko Hypponen, “cyber-security Jedi” and chief research officer at anti-virus firm F-Secure, did recently.
In a candid article for Wired published at the start of June, he admitted that the antivirus industry had been caught with its trousers down by what has been described by some as the most complex piece of malicious software ever created. (See below).
Known as Flame, the software is an example of a “spyware” infection, designed surreptitiously to record and transmit a record of actions taking place on a compromised system – from video and audio to the individual strokes of a keyboard – as well as offering access to sensitive and supposedly private information.
More striking than these capabilities, however, are two crucial factors: the sophistication of Flame’s targeting, and its ability to evade detection. Flame’s targets were almost certainly a handful of computers operating sensitive aspects of nuclear programs in the Middle East. And, as soon became apparent after its discovery, it had been spreading across the world towards these machines for over two years, undetected. Until its purpose was due to be served, one of the most important pieces of malicious code in existence had to all intents and purposes been invisible.
All of which marks out Flame as a tool not of mere criminality, but of cyber-espionage: one developed by a state-sponsored intelligence program with the intent of gathering technical information of the most sensitive kind. Hence Hyponnen’s remarkably frank assessment: “We really should have been able to do better. But we didn’t. We were out of our league, in our own game.”
Sophisticated scams
Cyber-crime used to feel, if not like a game with rules, then at least like an arena of knowable motivations. Thanks to the internet, every petty criminal in the world suddenly had access to your front garden (metaphorically speaking) and would muster as much cunning as possible to break into your house – or at least your bank account.
Just a day after Iran had announced the discovery of Flame, I was speaking at the Thinking Digital conference in northeast England, where I listened to Hypponen outline one of the more ingenious of such scams. Once infected by the malware in question, your computer produces an official-looking message on startup claiming to be from the FBI.
It has been detected, the message says, that your hard drive contains a treasure trove of illicit materials, incriminating you in everything from terrorism to child pornography. Your entire system has been frozen, leaving you only two options: either click here to take the claim to “court” (a bogus dead end); or pay an instant fine to unlock your system. Some users, Hypponen went on to explain, actually paid the fine even though they knew it was a scam – because they couldn’t face the potential humiliation and suspicion of explaining what was going on.
Such attacks can be destructive, disturbing and costly. Yet it is, at least, clear what’s going on once you see behind the deceiving veil: what the scammers want (money); how they aim to get it; and what your recourses may be (download a fix; contact the police or civilian digital security experts). Even when it effectively entails taking your computer hostage, financial gain remains a comprehensible motive.
Raising alarms
What, though, is to be done when the actors involved are states themselves; or digital aggressors acting with the resources of a state behind them? Shrouded by plausible deniability on all sides, it’s increasingly clear that a kind of silent war is beginning online: one whose battles even the experts may only recognize after they’ve been fought, and whose potential targets encompass almost every system or service plugged into a computer.
Take Stuxnet, another complex piece of code thought to have targeted Iran’s nuclear facilities. Only now, a full two years after its discovery, are we beginning to get to the bottom of who launched the attack. And, as Hypponen warns, “it’s highly likely there are other similar attacks already underway that we haven’t detected yet.”
If this sounds alarmist, well, that’s because it is. If your nuclear research programme is under covert digital attack, the police aren’t likely to be of much use – but it’s far from clear at the moment who else might do a better job. Hence the current global recruitment drive among military contractors for technology experts; and hence an online arms race that has seen Tehran alone spend a reported billion dollars on its offensive and defensive digital capabilities in recent months.
Eugene Kaspersky, the man who owns the lab that first identified Flame, has called on nations to stop releasing these weapons “before it’s too late” – words echoed by the United Nations this week. The tools of cyber-espionage, he points out, are not like conventional weapons. Once released, they are free to spread beyond their original purpose or target. And when that happens, they can be analysed, tweaked, built upon and relaunched. They are “cyber boomerangs” that can come straight back at a nation with potentially devastating consequences.
Even assuming Kaspersky’s warning is heeded, however, “too late” remains an alarmingly elusive notion in the context of espionage. In Donald Rumsfeld’s immortal words, we live in an age of “unknown unknowns”: of ignorances that we don’t even know we’re ignorant of. We have no idea what threats may arise next in the digital realm – not least because, somewhere, they may already have beaten us in a battle we didn’t even know we were fighting.
http://www.bbc.com/future/story/20120608-system-failure-in-cyber-warfare
AND:
Why Antivirus Companies Like Mine Failed to Catch Flame and Stuxnet
By Mikko Hypponen
June 1, 2012
A couple of days ago, I received an e-mail from Iran. It was sent by an analyst from the Iranian Computer Emergency Response Team, and it was informing me about a piece of malware their team had found infecting a variety of Iranian computers. This turned out to be Flame: the malware that has now been front-page news worldwide.
When we went digging through our archive for related samples of malware, we were surprised to find that we already had samples of Flame, dating back to 2010 and 2011, that we were unaware we possessed. They had come through automated reporting mechanisms, but had never been flagged by the system as something we should examine closely. Researchers at other antivirus firms have found evidence that they received samples of the malware even earlier than this, indicating that the malware was older than 2010.
Mikko Hypponen
What this means is that all of us had missed detecting this malware for two years, or more. That’s a spectacular failure for our company, and for the antivirus industry in general.
It wasn’t the first time this has happened, either. Stuxnet went undetected for more than a year after it was unleashed in the wild, and was only discovered after an antivirus firm in Belarus was called in to look at machines in Iran that were having problems. When researchers dug back through their archives for anything similar to Stuxnet, they found that a zero-day exploit that was used in Stuxnet had been used before with another piece of malware, but had never been noticed at the time. A related malware called DuQu also went undetected by antivirus firms for over a year.
Stuxnet, Duqu and Flame are not normal, everyday malware, of course. All three of them were most likely developed by a Western intelligence agency as part of covert operations that weren’t meant to be discovered. The fact that the malware evaded detection proves how well the attackers did their job. In the case of Stuxnet and DuQu, they used digitally signed components to make their malware appear to be trustworthy applications. And instead of trying to protect their code with custom packers and obfuscation engines — which might have drawn suspicion to them — they hid in plain sight. In the case of Flame, the attackers used SQLite, SSH, SSL and LUA libraries that made the code look more like a business database system than a piece of malware.
Someone might argue that it’s good we failed to find these pieces of code. Most of the infections occurred in politically turbulent areas of the world, in countries like Iran, Syria and Sudan. It’s not known exactly what Flame was used for, but it’s possible that if we had detected and blocked it earlier, we might have indirectly helped oppressive regimes in these countries thwart the efforts of foreign intelligence agencies to monitor them.
But that’s not the point. We want to detect malware, regardless of its source or purpose. Politics don’t even enter the discussion, nor should they. Any malware, even targeted, can get out of hand and cause “collateral damage” to machines that aren’t the intended victim. Stuxnet, for example, spread around the world via its USB worm functionality and infected more than 100,000 computers while seeking out its real target, computers operating the Natanz uranium enrichment facility in Iran. In short, it’s our job as an industry to protect computers against malware. That’s it.
Yet we failed to do that with Stuxnet and DuQu and Flame. This makes our customers nervous.
The truth is, consumer-grade antivirus products can’t protect against targeted malware created by well-resourced nation-states with bulging budgets. They can protect you against run-of-the-mill malware: banking trojans, keystroke loggers and e-mail worms. But targeted attacks like these go to great lengths to avoid antivirus products on purpose. And the zero-day exploits used in these attacks are unknown to antivirus companies by definition. As far as we can tell, before releasing their malicious codes to attack victims, the attackers tested them against all of the relevant antivirus products on the market to make sure that the malware wouldn’t be detected. They have unlimited time to perfect their attacks. It’s not a fair war between the attackers and the defenders when the attackers have access to our weapons.
Antivirus systems need to strike a balance between detecting all possible attacks without causing any false alarms. And while we try to improve on this all the time, there will never be a solution that is 100 percent perfect. The best available protection against serious targeted attacks requires a layered defense, with network intrusion detection systems, whitelisting against known malware and active monitoring of inbound and outbound traffic of an organization’s network.
This story does not end with Flame. It’s highly likely there are other similar attacks already underway that we haven’t detected yet. Put simply, attacks like these work.
Flame was a failure for the antivirus industry. We really should have been able to do better. But we didn’t. We were out of our league, in our own game.
http://www.wired.com/threatlevel/2012/06/internet-security-fail/
|
"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
Arthur Schopenhauer, Philosopher, 1788-1860
"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
John F. Kennedy |
|
Big Bunny
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| | Re: New Millenium Technology VIII
« Reply #141 on Jun 9, 2012, 11:32am » | |
New Property of Flames Sparks Advances in Technology
ScienceDaily (June 7, 2012) — Chemists at UCL have discovered a new property of flames, which allows them to control reactions at a solid surface in a flame and opens up a whole new field of chemical innovation.
Published in the journal Angewandte Chemie, authors of the new study have discovered their previous understanding of how flames interact with a solid surface was mistaken. For the first time, they have demonstrated that a particular type of chemistry, called redox chemistry, can be accurately controlled at the surface.
This finding has wide implications for future technology, for example in detection of chemicals in the air, and in developing our understanding of the chemistry of lightning. It also opens up the possibility of being able to perform nitrogen oxide and carbon dioxide electrolysis at the source for the management of green house gases.
Results of the study show that depending on the chemical make-up of the flame, scientists can record a distinctive electrical fingerprint. The fingerprint is a consequence of the behaviour of specific chemical species at the surface of a solid conducting surface, where electrons can exchange at a very precise voltage.
Dr Daren Caruana, from the UCL Department of Chemistry, said: "Flames can be modelled to allow us to construct efficient burners and combustion engines. But the presence of charged species or ions and electrons in flames gives them a unique electrical property."
Dr Caruana added: "By considering the gaseous flame plasma as an electrolyte, we show that it is possible to control redox reactions at the solid/gas interface."
The team developed an electrode system which can be used to probe the chemical make-up of flames. By adding chemical species to the flame they were able to pick up current signals at specific voltages giving a unique electrochemical finger print, called a voltammogram.
The voltammograms for three different metal oxides -- tungsten oxide, molybdenum oxide and vanadium oxide -- are all unique. Furthermore, the team also demonstrated that the size of the current signatures depend on the amount of the oxide in the flame. Whilst this is possible and routinely done in liquids, this is the first time to be shown in the gas phase.
UCL chemists have shown that there are significant differences between solid/gas reactions and their liquid phase equivalents. Liquid free electrochemistry presents access to a vast number of redox reactions, current voltage signatures that lie outside potential limits defined by the liquid.
The prospect of new redox chemistries will enable new technological applications such as electrodeposition, electroanalysis and electrolysis, which will have significant economic and environmental benefits.
Dr Caruana said: "The mystique surrounding the properties of fire has always captivated our imagination. However, there are still some very significant technical and scientific questions that remain regarding fire and flame. "
Story Source:
The above story is reprinted from materials provided by University College London.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
Journal Reference:
Atif Elahi, Toks Fowowe, Daren J. Caruana. Dynamic Electrochemistry in Flame Plasma Electrolyte. Angewandte Chemie, 2012; DOI: 10.1002/ange.201200226
http://www.sciencedaily.com/releases/2012/06/120607122313.htm
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"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
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"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
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| | Re: New Millenium Technology VIII
« Reply #142 on Jun 9, 2012, 11:46am » | |
Tabletop X-Ray to Image Nanoworld: All the Colors of a High-Energy Rainbow, in a Tightly Focused Beam
![[image]](http://imageshack.us/a/img72/620/120607142351large.jpg "[image]")
This art represents an electron being ripped from an atom by a strong laser field, which stretches its quantum wave function over hundreds of atomic sizes. Just as electrons accelerated in an X-ray tube emit bremsstrahlung radiation, electrons accelerated by a laser can emit rainbows of coherent X-rays in a laser-like beam. X-ray light is "invisible to the human eye but is important for being able to 'see' the fine details and fastest motions of the nanoworld." (Credit: Tenio Popmintchev, JILA and University of Colorado at Boulder)
ScienceDaily (June 7, 2012) — For the first time, researchers have produced a coherent, laser-like, directed beam of light that simultaneously streams ultraviolet light, X-rays, and all wavelengths in between.
One of the few light sources to successfully produce a coherent beam that includes X-rays, this new technology is the first to do so using a setup that fits on a laboratory table.
An international team of researchers, led by engineers from the NSF Engineering Research Center (ERC) for EUV Science and Technology, reports their findings in the June 8, 2012, issue of Science.
By focusing intense pulses of infrared light--each just a few optical cycles in duration--into a high-pressure gas cell, the researchers converted part of the original laser energy into a coherent super-continuum of light that extends well into the X-ray region of the spectrum.
The X-ray burst that emerges has much shorter wavelengths than the original laser pulse, which will make it possible to follow the tiniest, fastest physical processes in nature, including the coupled dance of electrons and ions in molecules as they undergo chemical reactions, or the flow of charges and spins in materials.
"This is the broadest spectral-bandwidth, coherent-light source ever generated," says engineering and physics professor Henry Kapteyn of JILA at the University of Colorado at Boulder, who led the study with fellow JILA professor Margaret Murnane and research scientist Tenio Popmintchev, in collaboration with researchers from the Vienna University of Technology, Cornell University and the University of Salamanca.
"It definitely opens up the possibility to probe the shortest space and time scales relevant to any process in our natural world other than nuclear or fundamental particle interactions," Kapteyn adds. The breakthrough builds upon earlier discoveries from Murnane, Kapteyn and their colleagues to generate laser-like beams of light across a broad spectrum of wavelengths.
The researchers use a technique called high-harmonic generation (HHG). HHG was first discovered in the late 1980s, when researchers focused a powerful, ultra-short laser beam into a spray of gas. The researchers were surprised to find that the output beam contained a small amount of many different wavelengths in the ultraviolet region of the spectrum, as well as the original laser wavelength. The new ultraviolet wavelengths were created as the gas atoms were ionized by the laser.
"Just as a violin or guitar string will emit harmonics of its fundamental sound tone when plucked strongly, an atom can also emit harmonics of light when plucked violently by a laser pulse," adds Murnane. "The laser pulse first plucks electrons from the atoms, before driving them back again where they can collide with the atoms from which they came. Any excess energy is emitted as high-energy ultraviolet photons."
Like many phenomena, when HHG was first discovered, there was little science to explain it, and it was considered more a curious phenomenon than a potentially useful light source. After years of work, scientists eventually understood how very high harmonics were emitted, however there was one major challenge that most researchers gave up on--for most wavelengths in the X-ray region, the output HHG beams were extremely weak.
Murnane, Kapteyn and their students realized that there might be a chance to overcome that challenge and turn HHG into a useful X-ray light source--the tabletop-scale X-ray laser that has been a goal for laser science since shortly after the laser was first demonstrated in 1960.
"This was not an easy task," says Murnane. "Unlike a laser--which gets more intense as more energy is pumped into the system--in HHG, if the laser hits the atoms too hard, too many electrons are liberated from the gas atoms, and those electrons cause the laser light to speed up. If the speed of the laser and X-rays do not match, there is no way to combine the many X-ray waves together to create a bright output beam, since the X-ray waves from different gas atoms will interfere destructively."
Popmintchev and JILA graduate student Ming-Chang Chen worked out conditions that enable X-ray waves from many atoms in the gas to interfere constructively. The key was to use a relatively long-wavelength, mid-infrared laser and a high pressure gas cell that also guides the laser light. The resulting bright, X-ray beams maintain the coherent, directed beam qualities of the laser that drives the process.
The HHG process is effective only when the atoms are hit "hard and fast" by the laser pulses, with durations nearing 10-14 seconds--a fundamental limit representing just a few oscillations of the electromagnetic fields. Murnane and Kapteyn pioneered the technology for generating such light pulses in the 1990s, and used those lasers to develop and utilize HHG-based light sources in the extreme-ultraviolet (EUV) region of the spectrum in the 2000s. However, while researchers were using those lasers and the HHG technique to measure ever-shorter duration light pulses, they were stymied in how to make coherent light at shorter wavelengths in the more penetrating X-ray region of the spectrum.
The new paper in Science, under lead author and senior research associate Popmintchev, demonstrates that breakthrough, showing that the understanding of the HHG process the researchers developed is broadly valid.
"We would have never found this if we hadn't sat down and thought about what happens overall during HHG, when we change the wavelength of the laser driving it, what parameters have to be changed to make it work," added Kapteyn. "The amazing thing is that the physics seem to be panning out even over a very broad range of parameters. Usually in science you find a scaling rule that prevents you from making a dramatic jump, but in this case, we were able to generate 1.6 keV -- each X-ray photon was generated from more than 5,000 infrared photons."
When the researchers first started to work with ultrafast, mid-infrared lasers just a few years ago, they actually made a step backwards and generated bright extreme-ultraviolet light of longer wavelengths than they used to achieve in the lab.
"However, we discovered a new regime that helped us to realize, just on paper, that we could make this giant step forward towards much shorter electromagnetic wavelengths and generate bright, laser-like, soft and hard X-rays," adds Popmintchev. "What the experiments were suggesting back then looked too good to be true! It seemed that Mother Nature has combined together, in the most simple and beautiful way, all the microscopic and macroscopic physics. Now, we are already at X-ray wavelengths as short as roughly 7.7 angstroms, and we do not know the limit."
To truly control the beam of photons, the researchers needed to understand the HHG process at the atomic level and how X-rays emitted from individual atoms combine to form a coherent beam of light.
That understanding combines microscopic and macroscopic models of the HHG process with the fact that those interactions occur at very high intensity in a dynamically changing medium. The development of such a conceptual understanding took the last decade to develop.
The result was the realization that there is no fundamental limit to the energy of the photons that can be generated using the HHG process. To obtain higher-energy photons, the system paradoxically begins with laser light using lower energy photons--specifically, mid-infrared lasers.
The JILA researchers demonstrated the validity of that principle in their labs in Colorado, but to achieve their breakthrough, the researchers traveled to Vienna with their beam-generating setup. There, they used a laser developed by co-author Andrius Baltuška and colleagues at the Vienna University of Technology--the world's most-intense ultrashort-pulse laser operating in the mid-infrared, with a wavelength of four microns.
"Thirty years ago, people were saying we could make a coherent X-ray source, but it would have to be an X-ray laser, and we'd need an atomic bomb as the energy source to pump it," said Deborah Jackson, the program officer who oversees the ERC's grant. "Now, we have these guys who understand the science fundamentals well enough to introduce new tricks for efficiently extracting energetic photons, pulling them out at X-ray wavelengths . . . and it's all done on a table-top!"
In addition to achieving the high energy, the increasingly broad spectrum opens a range of new applications.
"In an experiment using such a source, one energy region from the beam will correspond with one element, another with another element, and so on to simultaneously look at atoms across entire molecules, and that will allow us to see how charge moves from one part of a molecule to another as a chemical reaction is happening," adds Kapteyn. "It'll take us awhile to learn how to use this, but it's very exciting."
Story Source:
The above story is reprinted from materials provided by National Science Foundation.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
Journal Reference:
T. Popmintchev, M.-C. Chen, D. Popmintchev, P. Arpin, S. Brown, S. Alisauskas, G. Andriukaitis, T. Balciunas, O. D. Mucke, A. Pugzlys, A. Baltuska, B. Shim, S. E. Schrauth, A. Gaeta, C. Hernandez-Garcia, L. Plaja, A. Becker, A. Jaron-Becker, M. M. Murnane, H. C. Kapteyn. Bright Coherent Ultrahigh Harmonics in the keV X-ray Regime from Mid-Infrared Femtosecond Lasers. Science, 2012; 336 (6086): 1287 DOI: 10.1126/science.1218497
http://www.sciencedaily.com/releases/2012/06/120607142351.htm
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"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
Arthur Schopenhauer, Philosopher, 1788-1860
"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
John F. Kennedy |
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Big Bunny
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| | Re: New Millenium Technology VIII
« Reply #143 on Jun 9, 2012, 11:49am » | |
Quantum Computers Move Closer to Reality, Thanks to Highly Enriched and Highly Purified Silicon
ScienceDaily (June 7, 2012) — The quantum computer is a futuristic machine that could operate at speeds even more mind-boggling than the world's fastest super-computers.
Research involving physicist Mike Thewalt of Simon Fraser University offers a new step towards making quantum computing a reality, through the unique properties of highly enriched and highly purified silicon.
Quantum computers right now exist pretty much in physicists' concepts, and theoretical research. There are some basic quantum computers in existence, but nobody yet can build a truly practical one -- or really knows how.
Such computers will harness the powers of atoms and sub-atomic particles (ions, photons, electrons) to perform memory and processing tasks, thanks to strange sub-atomic properties.
What Thewalt and colleagues at Oxford University and in Germany have found is that their special silicon allows processes to take place and be observed in a solid state that scientists used to think required a near-perfect vacuum.
And, using this 28Si they have extended to three minutes -- from a matter of seconds -- the time in which scientists can manipulate, observe and measure the processes.
"It's by far a record in solid-state systems," Thewalt says. "If you'd asked people a few years ago if this was possible, they'd have said no. It opens new ways of using solid-state semi-conductors such as silicon as a base for quantum computing.
"You can start to do things that people thought you could only do in a vacuum. What we have found, and what wasn't anticipated, are the sharp spectral lines (optical qualities) in the 28Silicon we have been testing. It's so pure, and so perfect. There's no other material like it."
But the world is still a long way from practical quantum computers, he notes.
Quantum computing is a concept that challenges everything we know or understand about today's computers.
Your desktop or laptop computer processes "bits" of information. The bit is a fundamental unit of information, seen by your computer has having a value of either "1" or "0."
That last paragraph, when written in Word, contains 181 characters including spaces. In your home computer, that simple paragraph is processed as a string of some 1,448 "1"s and "0"s.
But in the quantum computer, the "quantum bit" (also known as a "qubit") can be both a "1" and a "0" -- and all values between 0 and 1 -- at the same time.
Says Thewalt: "A classical 1/0 bit can be thought of as a person being either at the North or South Pole, whereas a qubit can be anywhere on the surface of the globe -- its actual state is described by two parameters similar to latitude and longitude."
Make a practical quantum computer with enough qubits available and it could complete in minutes calculations that would take today's super-computers years, and your laptop perhaps millions of years.
The work by Thewalt and his fellow researchers opens up yet another avenue of research and application that may, in time, lead to practical breakthroughs in quantum computing.
Story Source:
The above story is reprinted from materials provided by Simon Fraser University.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
Journal Reference:
M. Steger, K. Saeedi, M. L. W. Thewalt, J. J. L. Morton, H. Riemann, N. V. Abrosimov, P. Becker, H.- J. Pohl. Quantum Information Storage for over 180 s Using Donor Spins in a 28Si 'Semiconductor Vacuum'. Science, 2012; 336 (6086): 1280 DOI: 10.1126/science.1217635
http://www.sciencedaily.com/releases/2012/06/120607154138.htm
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"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
Arthur Schopenhauer, Philosopher, 1788-1860
"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
John F. Kennedy |
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Big Bunny
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| | Re: New Millenium Technology VIII
« Reply #144 on Jun 9, 2012, 2:54pm » | |
Steel-Strength Plastics: Durable Plastic May Replace Metals
ScienceDaily (June 7, 2012) — As landfills overflow with discarded plastics, scientists have been working to produce a biodegradable alternative that will reduce pollution. Now a Tel Aviv University researcher is giving the quest for environmentally friendly plastics an entirely new dimension -- by making them tougher than ever before.
Prof. Moshe Kol of TAU's School of Chemistry is developing a super-strength polypropylene -- one of the world's most commonly used plastics -- that has the potential to replace steel and other materials used in everyday products. This could have a long-term impact on many industries, including car manufacturing, in which plastic parts could replace metallic car parts.
Durable plastics consume less energy during the production process, explains Prof. Kol. And there are additional benefits as well. If polypropylene car parts replaced traditional steel, cars would be lighter overall and consume less fuel, for example. And because the material is cheap, plastic could provide a much more affordable manufacturing alternative.
His research has been published in the journal Angewandte Chemie.
Better building blocks
Although a promising field of research, biodegradable plastics have not yet been able to mimic the durability and resilience of common, non-biodegradable plastics like polypropylene. Prof. Kol believes that the answer could lie in the catalysts, the chemicals that enable their production.
Plastics consist of very long chains called polymers, made of simple building blocks assembled in a repeating pattern. Polymerization catalysts are responsible for connecting these building blocks and create a polymer chain. The better the catalyst, the more orderly and well-defined the chain -- leading to a plastic with a higher melting point and greater strength and durability. This is why the catalyst is a crucial part of the plastic production process.
Prof. Kol and his team of researchers have succeeded in developing a new catalyst for the polypropylene production process, ultimately producing the strongest version of the plastic that has been created to date. "Everyone is using the same building blocks, so the key is to use different machinery," he explains. With their catalyst, the researchers have produced the most accurate or "regular" polypropylene ever made, reaching the highest melting point to date.
Using resources more efficiently
By 2020, the consumption of plastics is estimated to reach 200 million tons a year. Prof. Kol says that because traditional plastics aren't considered green, it's important to think creatively to develop this material, which has become a staple of daily life, with the least amount of harm to the environment. Cheaper and more efficient to produce in terms of energy consumption, as well as non-toxic, Prof. Kol's polypropylene is good news for green manufacturing and could revolutionize the industry. The durability of the plastic results in products that require less maintenance -- and a much longer life for parts made from the plastic.
Beyond car parts, Prof. Kol envisions a number of uses for this and related plastics, including water pipes, which he says could ultimately conserve water use. Drinking water for the home has been traditionally carried by steel and cement pipes. These pipes are susceptible to leakage, leading to waste and therefore higher water bills. But they are also very heavy, so replacing them can be a major, expensive operation.
"Plastic pipes require far fewer raw materials, weighing ten times less than steel and a hundred times less than cement. Reduced leaking means more efficient water use and better water quality," Prof. Kol explains. The replacement of steel water pipes by those made of plastic is becoming more common, and the production of plastics with even greater strength and durability will make this transition even more environmentally-friendly.
Prof. Kol holds the Bruno Landesberg Chair in Green Chemistry at TAU.
Story Source:
The above story is reprinted from materials provided by American Friends of Tel Aviv University.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
Journal Reference:
Konstantin Press, Ad Cohen, Israel Goldberg, Vincenzo Venditto, Mina Mazzeo, Moshe Kol. Salalen Titanium Complexes in the Highly Isospecific Polymerization of 1-Hexene and Propylene. Angewandte Chemie International Edition, 2011; 50 (15): 3529 DOI: 10.1002/anie.201007678
http://www.sciencedaily.com/releases/2012/06/120607141644.htm
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"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
Arthur Schopenhauer, Philosopher, 1788-1860
"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
John F. Kennedy |
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Big Bunny
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| | Re: New Millenium Technology VIII
« Reply #145 on Jun 17, 2012, 10:04am » | |
Nanotechnology Used to Harness Power of Fireflies
![[image]](http://imageshack.us/a/img404/9061/120615114104.jpg "[image]")
Nanorods created with firefly enzymes glow orange. The custom, quantum nanorods are created in the laboratory of Mathew Maye, assistant professor of chemistry. (Credit: Image courtesy of Syracuse University)
ScienceDaily (June 15, 2012) — What do fireflies, nanorods, and Christmas lights have in common? Someday, consumers may be able to purchase multicolor strings of light that don't need electricity or batteries to glow. Scientists at Syracuse University found a new way to harness the natural light produced by fireflies (called bioluminescence) using nanoscience. Their breakthrough produces a system that is 20 to 30 times more efficient than those produced during previous experiments.
It's all about the size and structure of the custom, quantum nanorods, which are produced in the laboratory by Mathew Maye, assistant professor of chemistry in SU's College of Arts and Sciences; and Rebeka Alam, a chemistry Ph.D. candidate. Maye is also a member of the Syracuse Biomaterials Institute. "Firefly light is one of nature's best examples of bioluminescence," Maye says. "The light is extremely bright and efficient. We've found a new way to harness biology for non-biological applications by manipulating the interface between the biological and non-biological components."
Their work, "Designing Quantum Rods for Optimized Energy Transfer with Firefly Luciferase Enzymes," was published online May 23 in Nano Letters and is forthcoming in print. Collaborating on the research were Professor Bruce Branchini and Danielle Fontaine, both from Connecticut College.
Fireflies produce light through a chemical reaction between luciferin and it's counterpart, the enzyme luciferase. In Maye's laboratory, the enzyme is attached to the nanorod's surface; luciferin, which is added later, serves as the fuel. The energy that is released when the fuel and the enzyme interact is transferred to the nanorods, causing them to glow. The process is called Bioluminescence Resonance Energy Transfer (BRET).
"The trick to increasing the efficiency of the system is to decrease the distance between the enzyme and the surface of the rod and to optimize the rod's architecture," Maye says. "We designed a way to chemically attach, genetically manipulated luciferase enzymes directly to the surface of the nanorod." Maye's collaborators at Connecticut College provided the genetically manipulated luciferase enzyme.
The nanorods are composed of an outer shell of cadmium sulfide and an inner core of cadmium seleneide. Both are semiconductor metals. Manipulating the size of the core, and the length of the rod, alters the color of the light that is produced. The colors produced in the laboratory are not possible for fireflies. Maye's nanorods glow green, orange, and red. Fireflies naturally emit a yellowish glow. The efficiency of the system is measured on a BRET scale. The researchers found their most efficient rods (BRET scale of 44) occurred for a special rod architecture (called rod-in-rod) that emitted light in the near-infrared light range. Infrared light has longer wavelengths than visible light and is invisible to the eye. Infrared illumination is important for such things as night vision goggles, telescopes, cameras, and medical imaging.
Maye's and Alam's firefly-conjugated nanorods currently exist only in their chemistry laboratory. Additional research is ongoing to develop methods of sustaining the chemical reaction -- and energy transfer -- for longer periods of time and to "scale-up" the system. Maye believes the system holds the most promise for future technologies that that will convert chemical energy directly to light; however, the idea of glowing nanorods substituting for LED lights is not the stuff of science fiction.
Story Source:
The above story is reprinted from materials provided by Syracuse University. The original article was written by Judy Holmes.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
Journal Reference:
Rabeka Alam, Danielle M. Fontaine, Bruce R. Branchini, Mathew M. Maye. Designing Quantum Rods for Optimized Energy Transfer with Firefly Luciferase Enzymes. Nano Letters, 2012; : 120523130524006 DOI: 10.1021/nl301291g
http://www.sciencedaily.com/releases/2012/06/120615114104.htm
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"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
Arthur Schopenhauer, Philosopher, 1788-1860
"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
John F. Kennedy |
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Big Bunny
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| | Re: New Millenium Technology VIII
« Reply #146 on Jun 18, 2012, 9:49pm » | |
Trial of pilotless planes
Britain
June 19, 2012
Trials that could lead to unmanned flights in British airspace will take place in the coming months.
The trials by defence company BAE Systems are part of a program, in which ''pilotless'' aircraft may be used for search and rescue, coastal patrols and eventually pave the way for the removal of the co-pilot on commercial flights.
Although a pilot is being used for take-off and landing, control of the aircraft during flights over the Irish Sea is left to a computer, which is supervised by a remote commander back on the ground.
It has a sophisticated weather detection system that will steer the plane away from bad weather and a ''visual sense and avoid'' system enables it to avoid obstacles, such as other planes.
Read more: http://www.smh.com.au/world/trial-of-pil....l#ixzz1yCglfVvR
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"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
Arthur Schopenhauer, Philosopher, 1788-1860
"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
John F. Kennedy |
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Big Bunny
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| | Re: New Millenium Technology VIII
« Reply #147 on Jun 22, 2012, 1:07pm » | |
21 June 2012 Last updated at 14:22 GMT
'Magnetic emulsions' could clean up oil spills
![[image]](http://imageshack.us/a/img17/126/61027277jex1440674de271.jpg "[image]")
A standard magnet can be used to pull magnetic emulsions along a capillary
Researchers have unveiled a molecule that can make "magnetic emulsions", which has the potential to revolutionise the chemical industry.
Emulsions are blends which normally do not mix, like oil and water.
The team's custom-made molecule, described in Soft Matter, acts as an "emulsifier", coating oily materials and acting to blend the liquids.
But because the molecule responds to magnetic fields, it could be put to use in cleaning up oil spills.
The work is an extension of the "magnetic soap" the team reported in January and published in the journal Angewandte Chemie.
The earlier work showed promise for industrial and cleanup applications, but study co-author Julian Eastoe of the University of Bristol said the new paper demonstrates "a practical application without a shadow of a doubt".
The idea of an "emulsion" in paint may be the only familiar use of the word, but emulsions are tremendously common in industrial chemicals and also in many products found under the kitchen sink.
It makes them part of an industry worth billions of pounds.
What is clear from the team's demonstrations is that their magnetic emulsions will be useful in the cleanup of oil spills.
"We're making emulsions from essentially seawater and the kind of oils that would be spilled, and we're seeing that we can manipulate them using a magnetic field," Mr Eastoe told BBC News.
Heads and tails
At the heart of both ideas are what are known as surfactants - short for surface-active agents - that are based on metal atoms, which respond to magnetic fields.
![[image]](http://imageshack.us/a/img521/7226/58048088mils1magonside.jpg "[image]")
Magnetic soap, shown here in a droplet attracted to a magnet, was the starting point of the research
These magnetic surfactants are long chains of atoms, with metal atoms at one end.
One end of these surfactant molecules is "hydrophilic", or water-loving, and the other "hydrophobic", or water-fearing.
In a mixture including water and oily substances, the molecules surround bubbles of oils, aligning themselves with their hydrophilic tails pointing outward into the water.
To achieve this effect, Prof Eastoe said the team changed their original formula.
"We've changed the identity of the magnetic component and made it much more active, by replacing what was iron by another iron complex or another complex of gadolinium," he said.
The result is that the magnetic molecules create emulsions even when added in small amounts to currently available surfactants - so they could be easily implemented into industrial or clean-up applications.
Prof Eastoe also says that the simple preparation of the molecules could mean they join a number of other approaches to deliver medicines to specific sites in the body using magnetic fields.
http://www.bbc.co.uk/news/science-environment-18521711
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"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
Arthur Schopenhauer, Philosopher, 1788-1860
"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
John F. Kennedy |
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Big Bunny
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| | Re: New Millenium Technology VIII
« Reply #148 on Jun 25, 2012, 12:43pm » | |
South African innovator takes water out of showering
By Enos Phosa
Posted 2012/06/18 at 10:51 am EDT
JOHANNESBURG, June 18, 2012 (Reuters) — With inspiration from a friend too lazy to take a shower and a few months of research on the Internet, South African university student Ludwick Marishane has won global recognition for an invention that takes the water out of bathing.
Marishane, a 22-year-old student at the University of Cape Town student invented a product called DryBath, a clear gel applied to skin that does the work of water and soap.
The invention, which won Marishane the 2011 Global Student Entrepreneur of the Year Award, has wide applications in Africa and other parts of the developing world where basic hygiene is lacking and hundreds of millions of people do not have regular access to water.
The product differs from the anti-bacterial hand washes by eliminating the heavy alcohol smell. It creates an odorless, biodegradable cleansing film with moisturizers.
He came up with the idea as a teenager in his poor rural home in the winter when a friend of his said bathing was too much of a bother, made all the worse by a lack of hot water.
"He was lazy and he happened to say, 'why doesn't somebody invent something that you can just put on your skin and you don't have to bathe'," said Marishane.
It was his "eureka" moment.
He then used his web-enabled mobile phone to search through Google and Wikipedia in pursuit of a formula. Six months later, he came up with DryBath and a obtained a patent.
The product is now manufactured commercially with clients including major global airlines for use on long-haul flights and governments for its soldiers in the field.
Marishane also sees it helping conserve water in the poorest parts of the world.
"DryBath will go a long way in helping communities".
http://www.newsdaily.com/stories/bre85h12q-us-safrica-water-shower/#
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"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
Arthur Schopenhauer, Philosopher, 1788-1860
"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
John F. Kennedy |
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Big Bunny
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| | Re: New Millenium Technology VIII
« Reply #149 on Jun 25, 2012, 1:38pm » | |
New Paints Prevent Fouling of Ships' Hulls
ScienceDaily (June 25, 2012) — The colonisation of hulls by algae, barnacles, mussels and other organisms is a major problem for both pleasure boats and merchant tonnage. In a joint project, researchers at the University of Gothenburg and Chalmers University of Technology, Sweden, have developed new environmentally-friendly and effective bottom paints to prevent this.
Fouling is a major problem, leading to higher fuel consumption and so increased air pollution. It can also cause the spread of alien species that do not belong in the local marine environment.
Effective biocides found
Researchers at the University of Gothenburg and Chalmers University of Technology have spent nine years developing new environmentally-friendly and effective antifouling paints through a joint research programme called Marine Paint.
The focus has been on a substance called medetomidine, which has proved highly effective against barnacles, considered to be the most problematic fouling organism.
To tackle other types of fouling as well (such as algae, mussels, sea squirts and moss animals), the researchers have developed a concept for producing optimised combinations of different antifouling agents, or biocides.
The idea behind these optimised blends is to combine many different biocides that are effective against different fouling organisms, and adjust the balance between them to eliminate all types of fouling.
To produce the recipes for these optimised blends, the researchers have also developed a model system where they weigh the effect of different biocides on different fouling organisms against their expected environmental risk. The blends are all equally effective but offer different levels of expected environmental risk.
Hi-tech paints
These optimised blends have been combined with hi-tech paint systems based on microcapsules -- microscopic capsules made out of a polymer material which slowly release the biocides from the paint into the water.
Field trials of painted test panels at the Sven Lovén Centre for Marine Sciences in Kristineberg have shown that the concept of optimised antifouling blends in bottom paints works very well.
Marine Paint's research results for medetomidine have been passed to the commercial partner I-Tech AB to ensure that they are put into practice, and the product is now being marketed under the name Selektope.
Marine Paint has been hosting a conference in Gothenburg on 14-15 May 2012 and presentED its results and placeD them in a wider context, with speakers and participants representing universities, colleges, industry, authorities, shipping companies, leisure boat owners and other interested parties, primarily from Sweden and Europe.
The Marine Paint research programme was funded by the Mistra Foundation for Strategic Environmental Research from 2003 to 2011.
Story Source:
The above story is reprinted from materials provided by University of Gothenburg, via AlphaGalileo.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
http://www.sciencedaily.com/releases/2012/06/120625064735.htm
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"All truth passes through three stages. First, it is ridiculed, second it is violently opposed, and third, it is accepted as self-evident."
Arthur Schopenhauer, Philosopher, 1788-1860
"In the final analysis, our most basic common link is that we all inhabit this small planet, breathe the same air, and we all cherish our children’s future."
John F. Kennedy |
| |
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