physic world

To celebrate the 2011 December AGU meeting, Rachel Berkowitz takes a look at the first paper published in Journal of Geophysical Research.

December 15, 2011

Published: December 15, 2011December 2011

By Rachel Berkowitz

Last week San Francisco hosted the 2011 fall meeting of the American Geophysical Union (AGU). It is natural to expect that many of the 20 000 scientists from around the world who attended will submit their findings to AGU’s Journal of Geophysical Research (JGR). But who submitted the first JGR article ever published

In 1967, NASA's Mariner 4 spacecraft was cruising through the solar system, not far from Earth, when something unexpected happened. 'Mariner 4 ran into a cloud of space dust,' says Bill Cooke of the Marshall Space Flight Center Space Environments Team. 'For about 45 minutes the spacecraft experienced a shower of meteoroids more intense than any Leonid meteor storm we've ever seen on Earth.' The impacts ripped away bits of insulation and temporarily changed the craft's orientation in space. Fortunately, the damage was slight and the mission's main objective--a flyby of Mars--had been completed two years earlier. But it could have been worse. 'There are many uncharted dust clouds in interplanetary space. Some are probably quite dense,' says Cooke. Most of these clouds are left behind by comets, others are formed when asteroids run into one another. 'We only know about the ones that happen to intersect Earth's orbit and cause meteor showers such as the Perseids or Leonids.' The Mariner 4 cloud was a big surprise.

Mapping these clouds and determining their orbits is important to NASA for obvious reasons: the more probes we send to Mars and elsewhere, the more likely they are to encounter uncharted clouds. No one wants their spaceship to be surprised by a meteor shower hundreds of millions of miles from Earth. Much of Cooke's work at NASA involves computer-modeling of cometary debris streams--long rivers of dust shed by comets as they orbit the sun. He studies how clumps form within the streams and how they are deflected by the gravity of planets (especially giant Jupiter). He and his colleagues also watch the sky for meteor outbursts here on Earth. 'It's a good way to test our models and discover new streams,' he says. One such outburst happened on June 27, 1998. Sky watchers were surprised when hundreds of meteors streamed out of the constellation Bootes over a few-hour period. Earth had encountered a dust cloud much as Mariner 4 had done years earlier.

The meteors of 1998 were associated with a well-known meteor shower called the June Bootids. Normally the shower is weak, displaying only a few meteors per hour at maximum. But in 1998 it was intense. Similar outbursts had occurred, with no regular pattern, in 1916, 1921, and perhaps 1927. The source of the June Bootids is comet 7P/Pons-Winnecke, which orbits the Sun once every 6.37 years. The comet follows an elliptical path that carries it from a point near the orbit of Earth to just beyond the orbit of Jupiter. Pons-Winnecke last visited the inner solar system in 2002. The comet's dusty trail is evidently clumpy. When our planet passes through a dense spot in the debris stream, a meteor shower erupts.

A penny-sized rocket thruster may soon power the smallest satellites in space.

The device, designed by Paulo Lozano, an associate professor of aeronautics and astronautics at MIT, bears little resemblance to today’s bulky satellite engines, which are laden with valves, pipes and heavy propellant tanks. Instead, Lozano’s design is a flat, compact square — much like a computer chip — covered with 500 microscopic tips that, when stimulated with voltage, emit tiny beams of ions. Together, the array of spiky tips creates a small puff of charged particles that can help propel a shoebox-sized satellite forward.

In Harvard’s Pierce Hall, the surface of a small germanium-coated gold sheet shines vividly in crimson. A centimeter to the right, where the same metallic coating is literally only about 20 atoms thicker, the surface is a dark blue, almost black. The colors form the logo of the Harvard School of Engineering and Applied Sciences (SEAS), where researchers have demonstrated a new way to customize the color of metal surfaces by exploiting a completely overlooked optical phenomenon.

Radar images from NASA's Cassini spacecraft reveal some new curiosities on the surface of Saturn's mysterious moon Titan, including a nearly circular feature that resembles a giant hot cross bun and shorelines of ancient seas. The results were presented today at the American Astronomical Society's Division of Planetary Sciences conference in Reno, Nev.

So far, astrophysicists thought that super-massive black holes can only influence their immediate surroundings. A collaboration of scientists at the Heidelberg Institute for Theoretical Studies (HITS) and in Canada and the US now discovered that diffuse gas in the universe can absorb luminous gamma-ray emission from black holes, heating it up strongly. This surprising result has important implications for the formation of structures in the universe. The results have just been published in 'The Astrophysical Journal“ and „Monthly Notices of the Royal Astronomical Society”.

NASA's Spitzer Space Telescope has detected light emanating from a 'super-Earth' planet beyond our solar system for the first time. While the planet is not habitable, the detection is a historic step toward the eventual search for signs of life on other planets.

'Spitzer has amazed us yet again,' said Bill Danchi, Spitzer program scientist at NASA Headquarters in Washington. 'The spacecraft is pioneering the study of atmospheres of distant planets and paving the way for NASA's upcoming James Webb Space Telescope to apply a similar technique on potentially habitable planets.'

The planet, called 55 Cancri e, falls into a class of planets termed super Earths, which are more massive than our home world but lighter than giant planets like Neptune. The planet is about twice as big and eight times as massive as Earth. It orbits a bright star, called 55 Cancri, in a mere 18 hours.

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The first observation of a cosmic effect theorized 40 years ago could provide astronomers with a more precise tool for understanding the forces behind the universe's formation and growth, including the enigmatic phenomena of dark energy and dark matter.

Proposed in 1972 by Russian physicists Rashid Sunyaev and Yakov Zel'dovich, the kSZ effect results when the hot gas in galaxy clusters distorts the cosmic microwave background radiation — which is the glow of the heat left over from the Big Bang — that fills our universe. Radiation passing through a galaxy cluster moving toward Earth appears hotter by a few millionths of a degree, while radiation passing through a cluster moving away appears slightly cooler

A clock accurate to within a tenth of a second over 14 billion years – the age of the universe – is the goal of research being reported this week by scientists from three different institutions. To be published in the journal Physical Review Letters, the research provides the blueprint for a nuclear clock that would get its extreme accuracy from the nucleus of a single thorium ion.

This RF ion trap holds individual thorium atoms while they are laser-cooled to near absolute zero temperature. (Click image for high-resolution version. Credit: Corey Campbell)

The US Department of Energy (DOE) will support the construction of three small nuclear reactors at its Savannah River Site in South Carolina. The reactors are designed to generate heat and electricity for use at remote facilities such as mines, oil fields or isolated communities. The three companies involved are Gen4 Energy (formerly Hyperion), Holtec International and NuScale Power.

When it comes to dissipating energy in the atmosphere, the humble raindrop punches way above its weight. Researchers in the US have shown that the energy lost as heat by falling liquid water and ice particles is on par with the energy that the wind loses to friction. The team suggests that with the increasing precipitation expected as a result of global warming, the energy sunk into rainfall could reduce the amount available to generate winds.

By Steven T. Corneliussen

Following two high-visibility commentaries reported here earlier, Pervez Hoodbhoy—an MIT-educated physicist, Pakistani public intellectual, and friend of America's physics community—continued a prolific January, adding three commentaries about world nuclear tensions. Again these opinion articles appeared in an affiliate of the International Herald Tribune and the New York Times, the Express Tribune, which says it "caters to the modern face of Pakistan" with the mission to defend "liberal values and egalitarian traditions."

By modifying a familiar tool in nanoscience - the Scanning Tunneling Microscope - a team at Cornell University's Laboratory for Atomic and Solid State Physics have been able to visualize what happens when they change the electronic structure of a "heavy fermion" compound made of uranium, ruthenium and silicon. What they learned sheds light on superconductivity - the movement of electrons without resistance -which typically occurs at extremely low temperatures and that researchers hope one day to achieve at something close to room temperature, which would revolutionize electronics.

The researchers found that, while at higher-temperatures magnetism is detrimental to superconductivity, at low temperatures in heavy fermion materials, magnetic atoms are a necessity. "We found that removing the magnetic atoms proved detrimental to the flow [of electrons]," said researcher Mohammad Hamidian. This is important, Hamidian explains, because "if we can resolve how superconductivity can co-exist with magnetism, then we have a whole new understanding of superconductivity, which could be applied toward creating high-temperature superconductors. In fact, magnetism at the atomic scale could become a new tuning parameter of how you can change the behavior of new superconducting materials that we make."

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Thin-film solar cells could be made far more efficient with the addition of bundles of carbon nanotubes. So say researchers at the Los Alamos National Laboratory in the US, who have shown that the bundles can be used to adeptly perform the two important steps for generating an electric current. It is first time this has been demonstrated in a single thin-film photovoltaic material.

The experiments themselves are carried out in this vacuum chamber. When the laser light hits the membrane, some of the light is reflected and some is absorbed and leads to a small heating of the membrane. The reflected light is reflected back again via a mirror in the experiment so that the light flies back and forth in this space and forms optical resonator (cavity). Changing the distance between the membrane and the mirror leads to a complex and fascinating interplay between the movement of the membrane, the properties of the semiconductor and the optical resonances and you can control the system so as to cool the temperature of the membrane fluctuations. Credit: Niels Bohr Institute

Boffins looking for the perfect alliance between science and technology have married quantum computing to the future of IT - the cloud.

The researchers have used quantum mechanics to encrypt heavy-duty number-crunching computing, thereby removing a major obstacle in the adoption of the cloud for many enterprises ؟- how safe is my data when it's hosted on someone else's computers

Pulsars are created when a star collapses to form a neutron star in which the magnetic moments of the neutrons are frozen in a particular direction – much like the atomic moments in a permanent magnetic. That is the claim of two physicists in Sweden, who believe that their theory can account for many of the unexplained properties of these astronomical oddities.

Every substance has the property of 'mass', which is the basic physical presence of matter. Matter occupies space. A physical mass contained within a physical space produces the physical property of 'density'. For practical purposes, we define density as the mass of material contained within a specific unitary volume, usually as grams per cubic centimeter. The density of a material is a reflection of the energy contained by the molecules that compose the material. Molecular energy is exhibited in molecules by various vibrational motions. The more energy the molecules contain, the more they vibrate. The higher the temperature, the more the molecules vibrate and bump into each other. This tends to push teh molecules apart so that fewer of them occupy the same volume of space as the temperature increases.

Posted on: Saturday October 29, 2011.

Researchers at Purdue University and the National Institute of Standards and Technology (NIST) have created a device small enough to fit on a computer chip that converts continuous laser light into numerous ultrashort pulses, a technology that might have applications in more advanced sensors, communications systems and laboratory instruments.

'These pulses repeat at very high rates, corresponding to hundreds of billions of pulses per second,' said Andrew Weiner, the Scifres Family Distinguished Professor of Electrical and Computer Engineering.