Soon, lasers may trigger showers on demand

May 3, 2010 By Leave a Comment

London, May 3 (ANI): Shooting lasers into the air can elicit the formation of water droplets, and scientists claim that the technique could one day help to induce rain artificially.

For a long time, efforts to artificially trigger rain have focussed on ”cloud seeding” — scattering small particles of silver iodide into the air to act as ”condensation nuclei”, or centres around which rain droplets can grow.

“The problem is, it”s still not clear that cloud seeding works efficiently. There are also worries about how safe adding silver iodide particles into the air is for the environment,” Nature quoted optical physicist Jerome Kasparian at the University of Geneva, Switzerland, as saying.

The researchers thought that there might be a more environmentally friendly alternative.

Firing a laser beam made up of short pulses into the air ionizes nitrogen and oxygen molecules around the beam to create a plasma, resulting in a ”plasma channel” of ionized molecules.

These ionized molecules could act as natural condensation nuclei, explained Kasparian.

To see if this technique could induce droplets, the researchers fired a high-powered laser through an atmospheric cloud chamber in the lab containing saturated air (see video).

They illuminated the chamber using a second, standard low-power laser, enabling them to see and measure any droplets produced.

As soon as the laser was fired, drops measuring about 50 micrometres wide formed along the plasma channel.

Over the next three seconds, the droplets grew in size to 80 micrometres as the smaller droplets coalesced.

Next, the researchers took the technique outside.

They tested their high-powered portable ”Teramobile laser” over a number of different nights and in various humidity conditions.

And they detected that the amount of condensation induced by monitoring how much the light from a second laser was back scattered by any droplets.

In low humidity conditions, the Teramobile laser did not induce droplets.

But when the humidity was high, the team measured up to 20 times more back-scattering after the Teramobile laser was fired than before, said Kasparian, suggesting that condensation droplets were forming.

“This is the first time that a laser has been used to cause condensation outdoors,” said Roland Sauerbrey, an expert on laser physics.

The results are published online in Nature Photonics1. (ANI)

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Helium rain explains scarcity of neon in Jupiter’s atmosphere

March 23, 2010 By Leave a Comment

Washington, March 23 (ANI): In a new research, scientists at the UC (University of California) Berkeley, US, have suggested that helium rain is the best way to explain the scarcity of neon in the outer layers of Jupiter.

Neon dissolves in the helium raindrops and falls towards the deeper interior where it re-dissolves, depleting the upper layers of both elements, consistent with observations.

“Helium condenses initially as a mist in the upper layer, like a cloud, and as the droplets get larger, they fall toward the deeper interior,” said UC Berkeley post-doctoral fellow Hugh Wilson, co-author of the research paper.

“Neon dissolves in the helium and falls with it. So, our study links the observed missing neon in the atmosphere to another proposed process, helium rain,” he added.

Wilson’s co-author, Burkhard Militzer, UC Berkeley assistant professor of earth and planetary science and of astronomy, noted that “rain” – the water droplets that fall on Earth – is an imperfect analogy to what happens in Jupiter’s atmosphere.

The helium droplets form about 10,000 to 13,000 kilometers (6,000-8,000 miles) below the tops of Jupiter’s hydrogen clouds, under pressures and temperatures so high that “you can’t tell if hydrogen and helium are a gas or a liquid,” he said.

They’re all fluids, so the rain is really droplets of fluid helium mixed with neon falling through a fluid of metallic hydrogen.

The two modelers embarked on their current research because of a discovery by the Galileo probe that descended through Jupiter’s atmosphere in 1995 and sent back measurements of temperature, pressure and elemental abundances until it was crushed under the weight of the atmosphere.

All elements seemed to be as slightly enriched compared to the abundance on the sun, which is assumed to be similar to the elemental abundances 4.56 billion years ago when the solar system formed, except for helium and neon.

Neon stood out because it was one-tenth as abundant as it is in the sun.

Their simulations showed that the only way neon could be removed from the upper atmosphere is to have it fall out with helium, since neon and helium mix easily, like alcohol and water.

Militzer and Wilson’s calculations suggest that at about 10,000 to 13,000 kilometers into the planet, where the temperature about 5,000 degrees Celsius and the pressure is 1 to 2 million times the atmospheric pressure on Earth, hydrogen turns into a conductive metal.

Helium, not yet a metal, does not mix with metallic hydrogen, so it forms drops, like drops of oil in water.

This provided an explanation for the removal of neon from the upper atmosphere. (ANI)

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Scientists create material that can repel hot water

July 16, 2009 By Leave a Comment

London, July 16 (ANI): In a breakthrough study, scientists from University of Minnesota in St Paul have developed a new material that can repel hot water.

The new discovery could help protect vulnerable members of the population such as elderly, children, physically impaired people from hot-water burns.

Scientists have long been working on producing water-repelling materials inspired by natural surfaces, such as lotus leaves.

These leaves have waxy hydrophobic – water hating – coating and a spiky surface texture that helps to trap small pockets of air beneath water droplets.

During the study, Yuyang Liu along with colleagues from Hong Kong Polytechnic University, reviewed studies suggesting carbon nanotubes are powerfully hydrophobic in their search for a material that can repel hot water as well as cold, and found that they seem indifferent to temperature.

To further improve resistance to hot water, the team added carbon nanotubes to Teflon – a substance commonly used as a non-stick coating on cookware.

The researchers later dipped a cotton fabric into the mix.

They found that the material is able to repel hot water, milk, coffee and tea at 75 degree Celsius – a sufficient temperature to cause scalding – without problems.

Moreover, the hot droplets retain a near spherical shape and roll off the material.

However, Liu insists that Teflon coating alone is not so effective. He said that carbon nanotubes create a dimpled surface texture on a nanoscopic scale – small enough to trap air even under drops of hot liquid and prevent droplet impalement on the surface.

Philippe Brunet at the Mechanics Laboratory of Lille, France, thinks the work is promising.

“It has been claimed that a dense carpet of nanowires, coated with ad-hoc chemistry, should have a very high robustness to impalement but he doesn’t think anyone has tested such materials against hot water before,” New Scientist quoted him as saying.

The study appears in Journal of Materials Chemistry. (ANI)

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Sand can behave like water

June 27, 2009 By Leave a Comment

Washington, June 25 (ANI): A new study by researchers at the University of Chicago has shown that sand can behave like water, in the sense that both share similar properties.

The researchers showed that dry granular materials such as sands, seeds and grains have properties similar to liquid, forming water-like droplets when poured from a given source.

The finding could be important to a wide range of industries that use “fluidized” dry particles for oil refining, plastics manufacturing and pharmaceutical production.

In a first-time accomplishment, physicists from the Materials Research Science and Engineering Center at the University of Chicago, led by Professor Heinrich M. Jaeger, used high-speed photography to measure minute levels of surface tension and detect droplet formation in flows of dry granular materials.

Until recently, studies of so-called “free falling granular streams” tracked shape changes in flows of dry materials, but were unable to observe the full evolution of the forming droplets or the clustering mechanisms involved.

“Previous studies of granular streams were able to detect clustering by performing experiments in vacuum and were able to establish that the clustering was not caused by the drag from the ambient air,” said Jaeger. “However, the cause of the clustering remained a mystery,” he added.

But in this new experiment, researchers measured nanoscale forces that cause droplet formation using a special co-moving apparatus devised for a high-speed, 80,000 dollars camera that captures images much like a skydiver might photograph a fellow jumper in free fall.

They observed falling 100-micrometer-diameter glass beads, or streaming sand, and found that forces as much as 100,000 times smaller than those that produce surface tension in ordinary liquids could cause droplet formation in granular streams and cause these dry streams to behave like an ultra-low-surface-tension liquid.

John Royer, the graduate student in physics at the University of Chicago, who developed the apparatus, and his colleagues also directly measured grain-to-grain interactions with an atomic force microscope.

“At first we thought grain-grain interactions would be far too weak to influence the granular stream,” said Royer.

“The atomic force microscopy surprised us by demonstrating that small changes in these interactions could have a large impact on the break up of the stream, conclusively showing that these interactions were actually controlling the droplet formation,” he added.

According to researchers, understanding how dry materials coalesce could create greater efficiencies in their transportation and manipulation. (ANI)

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Nano-raspberries may fight foggy windows, eyeglasses

May 25, 2009 By Leave a Comment

Washington, May 25 (ANI): Fogged-up car windshield is a safety hazard and a nuisance that affect millions of people. Existing technology, including sprays that must be reapplied to stay effective, has many drawbacks. Now, scientists in China have come up with a new way to make raspberry-shaped nanoparticles, which can give glass a permanent antifogging coating.

Scientists have been working on anti-fog technology for years.

Junhui He and colleagues knew that raspberry-shaped nanoparticles could be the ideal solution by disrupting the process in which water droplets fog glass.

However, there has been no commercially feasible way to make these particles until now.

The scientists described an efficient one-step method for making nano-raspberries.

In laboratory studies, the researchers coated glass slides with the particles, cooled the slide, and then exposed it to steam.

The researchers found that unlike ordinary glass, it remained crystal clear, opening the door to possible commercial applications.

Their study is scheduled for the June 11 edition of ACS’ The Journal of Physical Chemistry C, a weekly publication. (ANI)

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Self-cleaning walls and water-striding robots come closer to reality

May 5, 2009 By Leave a Comment

Washington, May 5 (ANI): What if scientists create self-cleaning walls and fabrics or even micro-scale robots that can walk on water? Well, researchers at the University of Nebraska-Lincoln and Japan’s RIKEN institute claim to have moved a step closer to realising such materials.

The researchers have revealed that their work is based on a study of a property called super hydrophobia, which is behind how water beads up and rolls off flowers, caterpillars and some insects, and how insects like water striders are able to walk effortlessly on water.

“A lot of people study this and engineers especially like the water strider because it can walk on water. Their legs are super hydrophobic and each leg can hold about 15 times their weight. ‘Hydrophobic’ means water really doesn’t like their legs and that’s what keeps them on top. A lot of scientists and engineers want to develop surfaces that mimic this from nature,” said Xiao Cheng Zeng, Ameritas university professor of Chemistry at UNL.

Zeng and his Japanese colleagues – Takahiro Koishi of the University of Fukui and RIKEN, Kenji Yasuoka of Keio University, and Shigenori Fujikawa and Toshikazu Ebisuzaki of RIKEN – have now come up with clues to developing the long-sought super hydrophobic materials. he researcher highlight the fact that caterpillars, water striders, and the lotus achieve super hydrophobia through a two-level structure – a hydrophobic waxy surface made super hydrophobic by the addition of microscopic hair-like structures that may be covered by even smaller hairs, greatly increasing the surface area of the organism and making it impossible for water droplets to stick.

They used the superfast supercomputer at RIKEN, the fastest in the world when the research started in 2005, to design a computer simulation to perform tens of thousands of experiments that studied how surfaces behaved under many different conditions.

The team used the supercomputer to “rain” virtual water droplets of different sizes and speeds on surfaces, which had pillars of various heights and widths and different amounts of space between the pillars.

The researchers observed that there was a critical pillar height, depending on the particular structure of the pillars and their chemical properties, beyond which water droplets cannot penetrate.

According to them, if the droplet can penetrate the pillar structure and reach the waxy surface, it is in the merely hydrophobic Wenzel state, named for Robert Wenzel, who found the phenomenon in nature in 1936.

The scientists further said if it the droplet cannot penetrate the pillars to touch the surface, the structure is in the super hydrophobic Cassie state, named for A.B.D. Cassie, who discovered it in 1942, and the droplet rolls away.

“This kind of simulation — we call it ‘computer-aided surface design’ — can really help engineers in designing a better nanostructured surface. In the Cassie state, the water droplet stays on top and it can carry dirt away. In the Wenzel state, it’s sort of stuck on the surface and lacks self-cleaning functionality. When you build a nanomachine — a nanorobot — in the future, you will want to build it so it can self-clean,” Zeng said.

Using the supercomputer enabled the researchers to conduct thousands more repetitions than would have been possible in a lab, and they didn’t have to worry about variables such as dirt, temperature and airflow. The team could even control the size of droplets down to the exact number of molecules.

A research paper describing the study has been published in the online edition of the Proceedings of the National Academy of Sciences. (ANI)

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Next gen space station firefighting tools designed to douse out fires in microgravity

April 6, 2009 By Leave a Comment

Washington, April 6 (ANI): US engineers are developing the next-generation of firefighting equipment specially designed to work in microgravity to douse out fires in space stations.

According to a report in Discovery News, with a new spaceship under development, NASA is investing in next-generation fire-fighting gear that is specially designed to work in microgravity.

“In space, fires are like spheres. They’re not shaped like what we have on earth,” said James Butz, vice president of operations for ADA Technologies.

The company has already received a grant from NASA to continue work on an extinguisher that coats fires in a fine mist.

The technology is one of two NASA is exploring for use aboard its Orion spacecraft, the follow-on program to the space shuttle.

“There are mainly three emergencies that we train for – a fire, a depressurisation, or if the atmosphere becomes not livable,” said Sandra Magnus, who returned last week from a four-month stay on the International Space Station.

“If the situation can’t be contained, we basically train to evacuate,” she added.

But, astronauts aboard Orion will not have that luxury.

“ADA’s technology would coat a flame in tiny droplets of mist, much like fog,” said Butz.

The key to getting the droplets small enough is to use compressed gas. The system uses water and nitrogen so it is non-toxic and has an unlimited shelf life.

Because oxygen and nitrogen will be aboard the spacecraft, the extinguisher can be refilled if needed.

The technology, which has been under development for about a decade, caught NASA’s eye about two and a half years ago.

The company’s most recent grant is intended to tweak the nozzle design to address issues raised by the surface tension of water droplets.

The other fire-fighting technology under development is water-based foam, which Butz says works well, but is messy in microgravity. (ANI)

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