Airborne laser to shoot ballistic missile as part of flight test

September 12, 2009 By Leave a Comment

London, September 12 (ANI): Soon, the Airborne Laser (ABL), built into a customized Boeing 747, is ready for flight tests, in which it will try to shoot a ballistic missile.

According to a report in New Scientist, the US Department of Defense’s Missile Defense Agency (MDA) has developed the ABL.

The ABL aims to focus a beam of laser energy in the megawatt range for several seconds onto a missile at a “militarily significant distance” – more than 100 kilometres.

So far, the laser has only operated at near full power on the ground. On August 18, it was fired successfully from the air, but at reduced power.

That, however, was no mean feat, as aircraft vibrations play havoc with the precisely aligned optical components needed to generate a laser beam.

Firing at full power poses other challenges as well.

At powers high enough to destroy missiles, any surface contamination or tiny flaw in the laser optics can absorb so much heat that they crack or shatter.

High-power laser beams also heat the air they pass through, creating perturbations that can disperse or divert the beam.

To counteract those effects, the ABL uses an adaptive system that senses atmospheric changes along its path and makes optical adjustments to compensate.

To test that system, the MDA plans a series of increasingly powerful shots at modified ballistic missiles loaded with sensors to measure the distribution of laser power on the target.

Engineers will assess each shot’s performance and use the results to fine-tune the adaptive optics.

Once this is done, the MDA will test the laser again in varying conditions, and attempt to destroy actual missiles.

The first of these tests is planned to take place late this year, with two more to follow in early 2010, according to an MDA spokeswoman. (ANI)

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New ‘Taliban killer’ sights for British troopers on Afghanistan frontier

September 10, 2009 By Leave a Comment

London, Sep 9(ANI): After reports of British soldiers facing weapons’ shortage in the Afghanistan frontier, a range of new thermal weapons’ sights has been launched to enable soldiers to dominate the battlefield in Afghanistan.

According to reports, the British Ministry of Defence will buy almost 11,000 new sights for 150 million pounds, allowing the Army to equip 95 infantry companies of more than 100 men.

As part of the Ministry of Defence’s Future Integrated Soldier Technology (Fist) programme troops have been issued with a small glass prism-like sight, which project a red laser dot. It would help a soldier to quickly align the red dot on an enemy who is very close and hit him with guaranteed accuracy.

“This means the infantryman can pick up the enemy coming in. At night the enemy’s field craft has to be pretty adept because he has to remain in dead ground all the way up to your position and that is hard yards. This will allow us to dominate the night,” The Telegraph quoted Col Bill Pointing, a former battalion commander in charge of the project, as saying.

“This will allow the infantry to operate quicker, better, at longer range, at night and in difficult weather conditions,” he added.

It will provide improved protection, day and night surveillance and target acquisition, and assistance with navigation, command and control and battle preparation.

The new thermal weapons’ sights would also allow soldiers to conduct surveillance and engage targets in all weather and light levels, including zero light where normal night sights would be rendered ineffective.

“There is a considerable improvement in terms of us infantry engaging the Taliban at very close quarters in the villages of Afghanistan, especially at night time. It will help us to put very effective fire into them,” said Cpl Ciaran Hanna of the Irish Guards. (ANI)

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Laser cooling may be used to create “exotic” states of matter

September 10, 2009 By Leave a Comment

Washington, September 9 (ANI): In a new study, scientists have determined that the technique of laser cooling could be used to create “exotic” states of matter.

According to a report in National Geographic News, in a new technique, Martin Weitz and Ulrich Vogl of the University of Bonn in Germany used a laser to bring the temperature of dense rubidium gas far below the normal point at which the gas becomes a solid.

Previous research had been able to use lasers to quickly “supercool” only very diluted gases.

But, “here’s a case where you shine a laser on something and it actually cools down, and not just a handful of atoms, but a macroscopic object,” said Trey Porto, a physicist with the National Institute of Standards and Technology’s laser-cooling group.

The process could be used to create fascinating new states of matter, according to the study authors.

“For example, if you can very quickly cool water much lower than zero Celsius (32 degrees Fahrenheit), where it would normally turn to ice, exotic crystalline and glassy states of matter would be predicted,” Weitz said.

The new technique could also be used in cooling mechanisms to boost the efficiency of some stargazing equipment, he added.

“If you could cool thermal cameras that look at the stars, they may have less noise and be more sensitive,” he said.

Since a laser’s color is linked to its intensity, the new technique is based on using a red laser in which the frequency has been adjusted so that the beam affects the atoms only when they collide with each other.

Weitz and Vogl shone this laser beam into gaseous rubidium atoms in a high-pressure “atmosphere” of argon.

In the experiment, the rubidium gas fell from 662 degrees Fahrenheit (350 degrees Celsius) to almost 536 degrees Fahrenheit (280 degrees Celsius) within mere seconds.

Much more research needs to be done before the laser-cooling process can be used in real-world applications, study co-author Weitz cautioned.

But, NIST’s Porto said the work already represents a major departure from traditional cooling of diluted gases, which are currently used for studying quantum effects or preparing gas samples for atomic clocks.

“I think the really amazing thing is that you can even get cooling in this regime, because it’s a really dense gas and a very different mechanism,” Porto said.

“Traditional cooling powers are so tiny. To cool a physical object by a measurable degree with a laser is amazing,” he added. (ANI)

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Scientists using laser light to generate underwater sound

September 6, 2009 By Leave a Comment

Washington, September 6 (ANI): The United States Naval Research Laboratory is working on a new technology that uses flashes of laser light to remotely create underwater sound.

Researchers behind the project say that the new technology has the potential to expand and improve both Naval and commercial underwater acoustic applications, including undersea communications, navigation, and acoustic imaging.

Dr. Ted Jones, a physicist in the Plasma Physics Division, is leading a team of researchers from the Plasma Physics, Acoustics, and Marine Geosciences Divisions in developing this acoustic source.

The researchers used a 532 nm laser pulse for their study at the Salt Water Tank Facility.

They also used air bubblers and controlled water and air temperatures to create ocean-like conditions in the laboratory.

The research team could efficiently convert light into sound by concentrating the light sufficiently to ionize a small amount of water, which then absorbed laser energy and superheats.

They said that the result was a small explosion of steam that could generate a 220 decibel pulse of sound.

Given that the driving laser pulse has the ability to travel through both air and water, the researchers say that a compact laser on either an underwater or airborne platform can be used for remote acoustic generation.

They believe that their method would be a significant addition to traditional direct backscattering acoustic data. (ANI)

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‘Buy one, get one free boob implant’ billboard in Wisconsin raises stink!

September 4, 2009 By Leave a Comment

Washington, Sept 4 (ANI): A Wisconsin cosmetic surgeon is raising eyebrows – thanks to the expert’s buy one, get one free breast implant offer!

A large billboard along Highway 41 has been erected by Hotchandani Laser and Vein Center in Appleton promoting the “unique” offer.

“In today’s economy we’re trying to come up with creative ads that’ll get people in the door,” Christine Martens, who works for Jones Sign and came up with the billboard for Hotchandani Laser and Vein Center, said.

Jones Sign says it has done its job by attracting clients.

“He’s already paid for the ad,” Martens said.

The owner of the cosmetic center, Dr. Gope Hotchandani, said: “This is a little different.

“It took me by surprise. We want to make sure we have a positive impression of what we’re doing. Kind of catchy, but borderline.”

However, a few in downtown Appleton are not too happy with it, reports Fox News.

“Very definitely too much, if it’s going to be on a billboard where teenagers see it,” Linda Naden said.

“I don’t have a problem with it,” Jim Wingrove said. “They advertise everything else.” (ANI)

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Soon, a portable optical atomic clock

September 4, 2009 By Leave a Comment

Berlin, September 4 (ANI): In a new research work, a team of scientists has shown how optical atomic clocks in the future might become more compact and even portable, maybe even travel to space.

The research was done by scientists from the Physikalisch-Technische Bundesanstalt (PTB) in Braunschweig, Germany.

Optical clocks like the strontium clock in the PTB could be the atomic clocks of the future; some of them though are already ten times more precise and stable than the best primary caesium atomic clocks.

Nowm they might also become more compact and even portable, maybe in the future even travel to space.

PTB scientists have shown how some fundamental difficulties, which a more simple set-up had previously hindered, could be avoided.

They already have a practical application in mind: the clock could help to determine geographical heights even more exactly than before.

An optical clock is so exact because its “pendulum” swings so quickly.

The “pendulum” of a caesium atomic clock swings even more quickly: that is, that microwave radiation which can bring about a spin change in each electron of a caesium atom.

Precisely the microwave frequency at which this effect is largest defines the second. An optical atomic clock works with the still higher frequency of optical radiation – that is with an even faster pendulum.

As the movement of the atoms leads to very large frequency shifts through the Doppler effect, in the best of these clocks, the atoms are slowed down to a hundredth of the speed of a pedestrian in a first preparation step with the aid of laser cooling.

As the movement of the atoms leads to very large frequency shifts through the Doppler effect, in the best of these clocks the atoms are slowed down to a hundredth of the speed of a pedestrian in a first preparation step with the aid of laser cooling.

In a lattice clock, a further step then follows in which the atoms are held in potential wells.

These are created through the intensive light field of a laser. Several tens of thousands of strontium atoms are trapped in this so-called optical lattice.

The results of the investigation have shown how the optical lattice has to be dimensioned and how many atoms may be stored in it to operate a very accurate lattice clock also with strontium-88.

A clock is now being built on this basis that is more compact and more transportable than the previous lattice clocks. (ANI)

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Antarctica’s plumbing system more dynamic than previously believed

September 2, 2009 By Leave a Comment

Washington, Sept 2 (ANI): Scientists, using space-based lasers on a NASA satellite have created the most comprehensive inventory of lakes that actively drain or fill under Antarctica’s ice, which has revealed a continental plumbing system that is more dynamic than previously thought.

“Even though Antarctica’s ice sheet looks static, the more we watch it, the more we see there is activity going on there all the time,” said Benjamin Smith of the University of Washington in Seattle, who led the study.

Unlike most lakes, Antarctic lakes are under pressure from the ice above. That pressure can push melt water from place to place like water in a squeezed balloon.

The water moves under the ice in a broad, thin layer, but also through a linked cavity system. This flow can resupply other lakes near and far.

Understanding this plumbing is important, as it can lubricate glacier flow and send the ice speeding toward the ocean, where it can melt and contribute to sea level change.

But figuring out what’s happening beneath miles of ice is a challenge.

Researchers led by Smith analyzed 4.5 years of ice elevation data from NASA’s Ice, Cloud and land Elevation satellite (ICESat) to create the most complete inventory to date of changes in the Antarctic plumbing system.

The team has mapped the location of 124 active lakes, estimated how fast they drain or fill, and described the implications for lake and ice-sheet dynamics.

Smith, Helen Fricker, a geophysicist at the Scripps Institution of Oceanography, and colleagues extended their elevation analysis to cover most of the Antarctic continent and 4.5 years of data from ICESat’s Geoscience Laser Altimeter System (GLAS).

By observing how ice sheet elevation changed between the two or three times the satellite flew over a section every year, researchers could determine which lakes were active.

They also used the elevation changes and the properties of water and ice to estimate the volume change.

Only a few of the more than 200 previously identified lakes were confirmed active, implying that lakes in East Antarctica’s high-density “Lakes District” are mostly inactive and do not contribute much to ice sheet changes.

Most of the 124 newly observed active lakes turned up in coastal areas, at the head of large drainage systems, which have the largest potential to contribute to sea level change.

According to Robert Bindschadler, a glaciologist at NASA’s Goddard Space Flight Center, “The survey shows that most active subglacial lakes are located where the ice is moving fast, which implies a relationship.” (ANI)

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Scientists create world’s tiniest laser squeezing light

September 1, 2009 By Leave a Comment

London, August 31 (ANI): A team of American scientists have created the world’s smallest laser by squeezing light into a space smaller than a protein molecule.

Project leader Xiang Zhang, a professor at the University of California (UC) at Berkeley, says that the breakthrough heralds a revolution in optical technology.

The researcher believes that this advance may pave the way for “nanolasers” that can probe and manipulate DNA.

It may also prove helpful in creating super-fast computers and for telecommunications, the researcher says.

“This work shatters traditional notions of laser limits and makes a major advance towards applications in the biomedical, communications and computing fields,” the Scotsman quoted Prof. Zhang as saying.

According to Prof. Zhang, the new “plasmon” laser compresses light into a gap five nanometres wide, the size of a single protein molecule.

Plasmons are the wave-like motions of excited electrons on the surfaces of metals. Binding light to these oscillations allows it to be squeezed much further than normal.

“Plasmon lasers represent an exciting class of coherent light sources capable of extremely small confinement. This work can bridge the worlds of electronics and optics at truly molecular length scales,” said Prof. Zhang.

The research team behind this breakthrough hope that one day they will be able to shrink light down to the size of an electron’s wavelength, about one billionth of a metre.

A research article on their latest work has been published in the journal Nature. (ANI)

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Scientists create world’s smallest semiconductor laser

September 1, 2009 By Leave a Comment

Washington, August 31 (ANI): Researchers at the University of California (UC), Berkeley, have created the world’s smallest semiconductor laser, capable of generating visible light in a space smaller than a single protein molecule, an invention that breaks new ground in the field of optics.

The UC Berkeley team not only successfully squeezed light into such a tight space, but found a novel way to keep that light energy from dissipating as it moved along, thereby achieving laser action.

While it is traditionally accepted that an electromagnetic wave – including laser light – cannot be focused beyond the size of half its wavelength, research teams around the world have found a way to compress light down to dozens of nanometers by binding it to the electrons that oscillate collectively at the surface of metals.

This interaction between light and oscillating electrons is known as surface plasmons.

Scientists have been racing to construct surface plasmon lasers that can sustain and utilize these tiny optical excitations.

However, the resistance inherent in metals causes these surface plasmons to dissipate almost immediately after being generated, posing a critical challenge to achieving the buildup of the electromagnetic field necessary for lasing.

Zhang and his research team took a novel approach to stem the loss of light energy by pairing a cadmium sulfide nanowire – 1,000 times thinner than a human hair – with a silver surface separated by an insulating gap of only 5 nanometers, the size of a single protein molecule.

In this structure, the gap region stores light within an area 20 times smaller than its wavelength.

Because light energy is largely stored in this tiny non-metallic gap, loss is significantly diminished.

With the loss finally under control through this unique “hybrid” design, the researchers could then work on amplifying the light.

Trapping and sustaining light in radically tight quarters creates such extreme conditions that the very interaction of light and matter is strongly altered, the study authors explained.

“This work shatters traditional notions of laser limits, and makes a major advance toward applications in the biomedical, communications and computing fields,” said Xiang Zhang, professor of mechanical engineering and director of UC Berkeley’s Nanoscale Science and Engineering Center.

The achievement helps enable the development of such innovations as nanolasers that can probe, manipulate and characterize DNA molecules; optics-based telecommunications many times faster than current technology; and optical computing in which light replaces electronic circuitry with a corresponding leap in speed and processing power.

Scientists hope to eventually shrink light down to the size of an electron’s wavelength, which is about a nanometer. (ANI)

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Soon, soundwaves may help find early dental decay

August 25, 2009 By Leave a Comment

Washington, Aug 25 (ANI): Aussie researchers are developing a tool that can use sound waves to identify early stages of tooth decay by measuring the mineral content of teeth.

Tooth decay begins by acid-forming bacteria eating away at the enamel, causing minerals to leach from it, softening, and weakening the tooth.

Sometimes dentists can identify this demineralisation by seeing a change in the colour of the tooth, or by looking at x-rays.

They also use sharp probes that test the hardness of the enamel, and find where the rot has set in, but all such probes can be painful and cause unnecessary damage to the teeth.

But PhD researcher David Hsiao-Chuan Wang, from the University of Sydney, and colleagues are now developing a less invasive new technique to measure mineral content of teeth, using sound waves generated by laser pulses.

“We want to be able to be able to quantify mineral content of the dental enamel,” ABC Online quoted Wang as saying.

He added: “We can keep the laser power below a damaging threshold.”

Laser pulses aimed at the tooth set up a series of high frequency sound waves (ultrasound) that travel through the enamel surface, penetrating it to different depths.

As a soundwave moves through a demineralised part of the tooth, it changes its speed, which can be detected.

Each soundwave penetrates to different depths of the enamel, depending on its wavelength, enabling a profile of the tooth to be built up, showing where decay has begun.

The researchers first tested the system on different known materials, before testing it on extracted human tooth.

They still have to test the system on teeth in patients, but firstly they need to develop a convenient handheld device and obtain ethics permission to trial it in humans.

Wang said that a prototype of the hand-held device could be ready in two years.

Professor Ian Meyers of the Australian Dental Association has said that testing the technique in the mouth is important, as saliva affects the property of teeth enamel.

Meyers also said that when decay was detected early, fillings could be avoided by either stopping the demineralisation through better oral care.

Otherwise, it could also be possible to re-mineralise the tooth by using products specifically designed for this purpose.

He said that the new technique could add to the range of tools available for dentists to identify early stages of decay, as long as it is affordable

Wang has estimated that the new tool would cost “below 50,000 dollars”, and complement rather than replace conventional methods.

He said that the ultrasound technique would be particularly useful in research, especially in evaluating the effectiveness of remineralisation treatments.

The study has been published in the journal Optics Express. (ANI)

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Scientists unveil new way to clinically assess condition of tooth enamel using lasers

August 19, 2009 By Leave a Comment

Washington, August 19 (ANI): A collaborative study conducted by Australian and Taiwani researchers has led to a novel way to analyse the health of human teeth using lasers.

Described in the open-access journal Optics Express, the new approach involves measuring how the surface of a tooth responds to laser-generated ultrasound, which can help evaluate the mineral content of tooth enamel-the semi-translucent outer layer of a tooth that protects the underlying dentin.

This is the first time that any research team has been able to non-destructively measure the elasticity of human teeth, creating a method that can be used to assess oral health and predict emerging dental problems, such as tooth decay and cavities.

“The ultimate goal is to come up with a quick, efficient, cost-effective, and non-destructive way to evaluate the mineralization of human dental enamel,” says David Hsiao-Chuan Wang, a graduate student at the University of Sydney in Australia and first author on the paper.

For research purposes, “nano-indentation” is commonly used for gaining information on the elasticity of tooth enamel-a measure of its mineral content. However, nano-indentation destroys the measured regions of the enamel in the process and is only used to look at extracted teeth.

Wang and his advisor Simon Fleming, a physics professor at the University of Sydney’s Institute of Photonics and Optical Science, said that they wanted to develop a clinical method that would give as much information as nano-indentation and could be used to assess tooth enamel in actual patients while being completely non-destructive.

So, added the researchers, they developed a way to measure the elasticity of tooth enamel by adapting laser ultrasonic surface wave velocity dispersion, a method similar to what industrial engineers use to evaluate the integrity of thin films and metals.

They have revealed that their approach uses short duration laser pulses to excite ultrasonic waves that propagate along the surface, and penetrate only a small distance into a tooth.

The velocity of these waves is influenced by the elastic properties of the enamel on a tooth, and by detecting the ultrasonic waves with fibre optics at various points, they can determine the enamel’s elasticity, which is directly related to its mineralisation.

In their research article, the researchers have written that they could use this technique on extracted human teeth.

They admit that they have not yet tested the technique on a living person’s teeth, and that it will likely take several years before any eventual device is ready for use in the dentist’s office. (ANI)

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Scientists come a nano-step closer to weighing a single atom

July 29, 2009 By Leave a Comment

Melbourne, July 28 (ANI): In a new study, a team of scientists has understood how nanoparticles lose energy, thus coming a key step closer towards producing nanoscale detectors for weighing any single atom.

In this study, the team from the University of Melbourne, Argonne’s Center for Nanoscale Materials in Illinois and the University of Chicago synthesized and studied tiny gold rods with a width 5000 times smaller than the thickness of a human hair.

According to Professor John Sader from the Department of Mathematics and Statistics, University of Melbourne, in the same way as a classroom ruler decreases its frequency of vibration when an eraser is attached, nanomechanical mass sensors work by measuring their change in vibration frequency as mass is added.

The sensitivity of such nanomechanical devices is intimately connected to how much energy they displace.

So, researchers needed to understand how damping (loss of energy) is transferred both to the fluid surroundings and within the nanostructures.

It has not previously been possible to determine the rate at which vibrations in metal nanoparticle systems are damped, because of significant variations in the dimensions of the particles that have been studied – which masks the vibrations.

However, by studying a system of bipyramid-shaped gold nanoparticles with highly uniform sizes and shapes, the researchers overcame this limitation.

“Previous measurements of nanomechanical damping have primarily focused on devices where only one- or two-dimensions are nanoscale, such as long nanowires.

Our measurements and calculations provide insight into how energy is dissipated in devices that are truly nanoscale in all three-dimensions,” said Professor Sader.

Illuminating these bipyramidal nanoparticle systems with an ultra-fast laser pulse, set them vibrating mechanically at microwave frequencies.

These vibrations were long-lived and for the first time damping in these nanoparticle systems could be interrogated and characterized.

Moreover, the researchers separated out the portion of damping that is due to the material itself and that surrounding liquid for which they developed a parameter-free theoretical model that quantitatively explains this fluid damping.

Such ultrasensitive measurements could ultimately be used in areas such as medical research and diagnostics, enabling the detection of minuscule disease-causing agents such as viruses and prions at the single molecule level. (ANI)

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Laser technology creates new forms of metal and enhances aircraft performance

July 16, 2009 By Leave a Comment

Washington, July 16 (ANI): A team of scientists is using laser light technology to create new forms of metal and enhance aircraft performance.

The laser light technology is being used by AFOSR (Air Force Office of Scientific Research) funded researchers at the University of Rochester to help the military create new forms of metal that may guide, attract and repel liquids and cool small electronic devices.

Dr. Chunlei Guo and his team of researchers for the project discovered a way to transform a shiny piece of metal into one that is pitch black, not by paint, but by using incredibly intense bursts of laser light.

The black metal created, absorbs all radiation that shines upon it.

“With the creation of the black metal, an entirely new class of material becomes available to us, which may open up a whole new horizon for various applications,” said Guo.

“To do this, we looked at the reverse process of light absorption or light radiation and transformed the incandescent lamp into a bulb that glows twice as brightly as a regular light source, while consuming the same amount of energy,” Guo added.

The key to creating this super-filament is an ultra-brief, ultra-intense beam of light called a femtosecond laser pulse.

The laser burst lasts only a few quadrillionths of a second.

That intense blast forces the surface of the metal to form nano-structures and micro-structures that dramatically alter how efficiently light can radiate from the filament.

In addition to increasing the brightness of a bulb, Guo’s process can be used to tune the color of the light as well.

In addition to this research, Guo and his team have been working on creating technology that may enable the Air Force to create an additional kind of metal.

They are able to do this by using the femtosecond laser once again to alter the surface of metal and create unique nano- and micro-scale structures on the metal.

The unique nano-structures which are created from the laser affect the way liquid molecules interact with metal molecules.

The liquid spreads out over the metal because the nano-structures attach themselves to the liquid’s molecules more readily than the liquid’s molecules bond to each other.

The end result is the formation of a new kind of metal that can cool the plane’s electronic brain and heat pumps and allow the craft to retain dominance over any enemy that is also in flight. (ANI)

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Earliest stars in Universe may have been twins

July 10, 2009 By Leave a Comment

Washington, July 10 (ANI): Astrophysicists, using extremely detailed computer simulations, have determined that the earliest stars in the universe formed not only as individuals, but sometimes also as twins.

The robust simulations of the early universe were created by astrophysicists Matthew Turk and Tom Abel of the Kavli Institute for Particle Astrophysics and Cosmology, and Brian O’Shea of Michigan State University.

“We used to think that these stars formed by themselves, but now we see from our computer simulations that sometimes they have siblings,” said Turk.

“These stars provide the seeds of next generation star formation, so by understanding them we can better understand how other stars and galaxies formed,” he added.

To make this discovery, the researchers created an extremely detailed computer simulation of early star formation.

Into this virtual universe, they sprinkled primordial gas and dark matter as it existed soon after the Big Bang, data they obtained from observations of the cosmic microwave background.

This mostly uniform radiation – a faint glow of radio waves spread across the entire sky – contains subtle variations that reflect the beginning of all structure in the universe.

The simulations focused on the first Population III stars: massive, hot stars thought to have formed a mere several hundred million years after the Big Bang.

As the researchers watched their simulated universe evolve, waves of gas and dark matter swirled through the hot, dense universe.

As the universe cooled, gravity began to draw the matter together into clumps. In areas rich with matter, stars began to form.

In one out of the researchers’ five simulations, a single cloud of dust and dark matter formed into “twin” stars: one with a mass equivalent to about 10 suns, and one with a mass equivalent to about 6.3 suns.

Both of them were still growing at the end of the calculation and will likely grow to many times that mass.

“We ran five of these calculations starting from the beginning of the universe, and to our surprise one of them was special,” said Abel.

“This opens a whole new realm of research possibilities. These stars could evolve into two black holes, which could have created gravitational waves we could detect with an instrument like the Laser Interferometer Gravitational Wave Observatory,” he added.

“This will help us fine-tune our models for how structure in the universe formed and evolved. Understanding the very early stars helps us understand what we see today,” Turk said. (ANI)

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Cosmic ‘whips’ may be detected with gravitational waves

July 6, 2009 By Leave a Comment

London, July 6 (ANI): A new research has determined that cosmic ‘whips’, which are topological defects in space-time larger than the observable universe, can be detected with the help of gravitational waves.

Many theories predict the existence of cosmic strings.

They say that space-time should have universe-sized snags called ‘cosmic strings’ running across it, but none have yet been found.

That could be because they broke into a tangle of smaller strings and beads soon after the big bang, say scientists.

The imprint of their extremely high gravity was expected to be seen in the cosmic microwave background – the radiation left over from the big bang – or as gravitational lenses that bend distant light towards us.

But, no convincing evidence has been seen.

Ben Shlaer of Tufts University in Medford, Massachusetts, and colleagues, told New Scientist that the lack of evidence could be because the strings were unstable and split into smaller and smaller pieces soon after they formed.

The first strings could have been gigantic closed loops or extremely large fragments that terminated in “beads”.

These beads would have been so-called monopoles – analogous to a magnet’s north or south pole without its partner.

As the strings broke, the team’s analysis shows that their split ends would have been capped off by more monopoles, eventually leading to a universe filled with fragmented strings with beads at their ends.

In an infant universe, these high-tension strings would have been whipping around, accelerating the massive beads to relativistic speeds.

These would have generated tight beams of gravitational waves, which could still be traveling through space-time.

“It’s possible that if you wait long enough, one of those highly focused bursts would hit the Earth, and that would cause one of our gravitational wave detectors to chirp,” said Shlaer.

The first cosmic strings were unstable and split into small pieces capped by monopoles.

Those detectors include the Laser Interferometer Gravitational Observatory, which is currently being upgraded, and the upcoming Laser Interferometer Space Antenna.

“The possible frequency range of the waves is exceptionally large, “raising the hope of detection” of cosmic strings,” said theoretical physicist Henry Tye at Cornell University in Ithaca, New York. (ANI)

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New instrument can detect explosives up to range of 100 meters

July 4, 2009 By Leave a Comment

Washington, July 4 (ANI): Scientists have developed a new explosives detector with incredible sensitivity and a range of up to 100 meters that could save lives and thwart the efforts of terrorists.

The detector, developed by a team of researchers at Oak Ridge National Laboratory, is based on photo-induced acoustic spectroscopy (PIAS).

Using PIAS, the military and law enforcement agencies will have an instrument that is one-tenth the size of competing products.

At five pounds, it is one-fifth the weight and is about one-fifth the cost of the competition.

It works by illuminating the suspected explosive with an eye-safe laser and allowing the scattered light to be detected by a quartz crystal tuning fork.

After a series of subsequent steps, the instrument is able to identify a number of explosives without jeopardizing the safety of the operator.

Funding for research work into the development of the instrument was provided by the Department of Energy’s Office of Nonproliferation Research and Development and the Office of Naval Research. (ANI)

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France to provide Tiger combat helicopters to Pak

July 3, 2009 By 1 Comment

Islamabad, July 3 (ANI): France has agreed to provide Pakistan Tiger combat helicopters and other sophisticated military equipments to strengthen its abilities in taking on the rampant Taliban.

The Military Personal Staff Advisor to French President, Nicolas Sarkozy, Admiral Edouard Guillaud, who is heading a delegation here, said that the combat helicopters to be provided by France will be equipped with ground-to-ground missiles with semi-active laser seekers with a range of over eight kilometers.

The helicopters are fitted with advanced radars and can also be equipped with anti-tank missiles, The Dawn reports.

Admiral Guillaud held a series of meetings with President Asif Ali Zardari, Prime Minister Yousuf Raza Gilani, Chief of the Army Staff General Ashfaq Kayani and several other top officials here.

A French Embassy official said that the visit of the delegation was a follow-up to the recent France visit of Zardari and General Kayani.

The official said both France and Pakistan share a common goal against extremism, and the visits were aimed at bolstering bilateral ties in the field of defense and security between both nations.

“The fight against terrorism is a key matter of concern for the international community. Within the framework of our common goal to fight terrorism, this visit aims at strengthening our bilateral cooperation in the field of defence and security,” he said.

The official said that during the delegation’s meeting with Zardari, the two sides decided to extend ties, primarily in the field of defense, and the use of civilian nuclear technology for peaceful purposes. (ANI)

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Laser beam powered optical transistor may lead to ultrafast light-based computers

July 2, 2009 By Leave a Comment

London, July 2 (ANI): Swiss researchers have made an optical transistor that uses one laser beam to control another, an instrument that could form the heart of a future generation of ultrafast light-based computers.

Conventional computers are based on transistors, which allow one electrode to control the current moving through the device and are combined to form logic gates and processors.

According to a report in New Scientist, the new component achieves the same thing, but for laser beams, not electric currents.

A green laser beam is used to control the power of an orange laser beam passing through the device.

This offers another possible route to light-based rather than electronic, computing.

Such “photonic” computing is desirable because components using optical fibres carrying light could be much faster than those using wires to carry electricity.

However, previous attempts to make optical transistors for such circuits only produced very weak effects.

The new device could change that.

To make their device, Vahid Sandoghdar and colleagues at the Swiss Federal Institute of Technology in Zurich, suspended tetradecane, a hydrocarbon dye, in an organic liquid.

They then froze the suspension to -272 degrees Celsius using liquid helium – creating a crystalline matrix in which individual dye molecules could be targeted with lasers.

When a finely tuned orange laser beam is trained on a dye molecule, it efficiently soaks up most of it up – leaving a much weaker “output” beam to continue beyond the dye.

But when the molecule is also targeted with a green laser beam, it starts to produce strong orange light of its own and so boosts the power of the orange output beam.

This effect is down to the hydrocarbon molecule absorbing the green light, only to lose the equivalent energy in the form of orange light.

“That light constructively interferes with the incoming orange beam and makes it brighter,” said Sandoghar’s colleague Jaesuk Hwang.

Using the green beam to switch the orange output beam from weak to strong is analogous to the way a transistor’s control electrode switches a current between “on” and “off” voltages, and hence the 0s and 1s of digital data.

Doing it with a single molecule means billions could be packed into future photonic chips. (ANI)

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‘Laser dazzler’ to stop careless drivers without blinding them

July 2, 2009 By Leave a Comment

London, July 2 (ANI): Reports indicate that the Pentagon is developing a laser dazzler that will force drivers to stop without harming their eyes.

When a vehicle approaches a checkpoint at speed, ignoring warning signs to slow down, troops do not know whether the driver is simply careless or a suicide bomber.

This makes it necessary for troops to have a clear and harmless way of forcing drivers to stop.

Green laser dazzlers designed to temporarily blind drivers were sent to US forces in Iraq and Afghanistan for just this purpose.

But at short range they can damage the eye, and a number of US troops and civilians have ended up in hospital with eye injuries after “friendly fire” incidents.

US troops and civilians have been sent to hospital with eye injuries after ‘friendly fire’ incidents.

Now, according to a report in New Scientist, the US Department of Defense’s Joint Non-Lethal Weapons Directorate (JNLWD) in Quantico, Virginia is developing a pulsed laser designed to prevent eye damage.

Its wavelength means a portion of the light is absorbed by the vehicle windscreen, vaporising the outer layer of the glass and producing a plasma.

This absorbs the rest of the pulse and re-emits the energy as a brilliant white light that is dazzling but harmless.

Because the light is emitted from the windscreen, the effect on the driver’s eyes should be the same regardless of the vehicle’s distance from the laser.

According to Scott Griffiths of the JNLWD, a working prototype could be ready by next year. (ANI)

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Light therapy offers ‘non-invasive’ breast cancer treatment

June 30, 2009 By Leave a Comment

London, June 30 (ANI): A British doctor is pioneering a groundbreaking treatment for breast cancer which uses light to target and kill tumours without the need for surgery.

Cancer surgeon Mo Keshtgar is adapting a form of light therapy for skin cancer to be used in breast cancer.

The treatment is known as photodynamic therapy (PDT). It uses tumour killing drugs which are injected into the body, latch onto the tumour and then are activated from outside using a laser, reports The Telegraph.

Its plus point is that it does not involve surgery and leaves healthy cells around the tumour unaffected.

Trials will be conducted at London’s Royal Free Hospital.

Keshtgar, who unveiled the technique at this year’s Royal Society Summer Science Exhibition, said: “The key appeal of photodynamic therapy is that it attacks and destroys cancer cells while retaining the viability of the surrounding normal cells.

“Breast cancer can be particularly traumatic, with more invasive treatments leaving physical and emotional scars. Our treatment will keep the structure of the connective tissue intact meaning the breast does not become deformed or lose shape.” (ANI)

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