Tag Archives: stars

Gigantic Baby Stars Discovered in Cloud of Space Dust

Written by XARIUSOUND. Posted on April 17, 2010. Filed under Science. Tagged Aeronautics, galaxies, galaxy, space, stars. No comments.

The previously undiscovered protostars are the small points of orangey light in the center of the image. They are up to 10 times more massive than the sun.

The Herschel Space Observatory, operated by the European Space Agency, obtained the new image, which is a composite of three different wavelengths of light all in the infrared part of the spectrum. Infrared light waves are longer and scatter less than visible light, allowing scientists to probe dust-shrouded areas of space. In this image, the shortest wavelength is blue, the medium green, and the longest red.

The intense star-forming region of the Milky Way is about 5,000 light-years away in the direction of the constellation Monoceros, the Unicorn. This image shows only part of the massive cloud of dust. If the whole thing, seen below, were visible to the naked eye, it would be large in the sky, appearing around five times the size of a full moon.

Stars: Five Ghosts

Written by XARIUSOUND. Posted on March 10, 2010. Filed under Audio. Tagged Amy Milan, Five Ghosts, stars, Vagrant. No comments.

We can add another name to the list of big indie bands releasing new albums this spring: Stars. The arch, dramatic Canadian indie poppers will release The Five Ghosts, their fifth studio album, on June 22.

This will be the first Stars album since 2007′s In Our Bedroom After the War, and it’ll also be the first release on the band’s own new label Soft Revolution, which will be licensed outside Canada via Vagrant.

All five members of the band contributed songwriting to the album, and Broken Social Scene/Apostle of Hustle member Andrew Whiteman makes a guest appearance. The first single, “Fixed”, features lead vocals from Stars co-leader AmyMillan. In a statement, Millan says, “We have never written an album with this much cohesion and unity. It is the first time we’ve had the luxury of being together in a huge room writing songs off the floor.”

Before the album drops, the band will tour clubs playing The Five Ghosts in its entirety, as well as fan-chosen old jams “Take Me to the Riot”, “Your Ex-Lover Is Dead”, and “Ageless Beauty”. They haven’t announced any of their dates yet, so keep an eye out.

Early Galaxies

Written by XARIUSOUND. Posted on February 11, 2010. Filed under Science. Tagged astronomy, galaxies, space, stars. No comments.

The mystery of why galaxies formed early in the history of the universe give birth to more stars than modern ones has been solved. An abundance of dense, cold gas fueled rapid star formation in these early galaxies, according to a new study.

Astronomers collected signals from 19 different 8- to 10-billion-year old galaxies scattered across the northern sky. These early-universe stellar nurseries had much more interstellar gas — dense, hydrogen-rich clouds at a chilly minus 441 to minus 414 degrees Fahrenheit — than their modern counterparts.

“This is really pioneering work,” said astrophysicist Kai Noeske of the Harvard Smithsonian Center for Astrophysics. ”It unambiguously confirms that these galaxies really are more gas-rich, so the reason they made more stars back in the day is that they had more fuel to burn.”

Scientists study distant galaxies because the light they sent out billions of years ago is only now reaching us, and can therefore tell us about conditions early in the universe’s 13.7-billion-year history.

No one knew why stars form more than 10 to 100 times more often in distant, massive galaxies than they do in local galaxies of the same mass, said astronomer Linda Tacconi of the Max Planck Institute for Extraterrestrial Physics in Germany, lead author of the Feb. 10 Nature study.

Some scientists had guessed that these early galaxies contained more cold interstellar gas, which fueled the frenetic birth of stars. Others argued that these ancient galaxies had the same amount of gas as the Milky Way, but that suns formed in short, furious starbursts as these galaxies collided, Noeske said.

Determining which theory was right was difficult. The cold, dense gas clouds emit such faint, low-energy light that even the most sensitive instruments can barely detect them. Just a few years ago, Tacconi’s team searched for signals from these galaxies, but failed, she said.

The group was finally able to answer the question by adding more-sensitive detectors to the IRAM Plateau de Bure Interferometer, an array of millimeter-wavelength radio telescopes located at 7,381 feet in the French Alps.

Ultimately, the team wanted to know how much hydrogen filled these early galaxies, because it is by far the most abundant element in the universe and in interstellar gas clouds. But hydrogen emissions from these distant objects are simply too hard to detect, Tacconi said.

Instead, they measured the light emitted from carbon monoxide molecules. As these molecules rotate, they shift from one energy state to another. As they shift, “they emit photons, and that radiation is what we see as an emission line at a specific wavelength,” Tacconi said.

The amount of light emitted from these spinning molecules revealed the fraction of each galaxy made up of carbon monoxide. Carbon monoxide and hydrogen are found in almost the same ratio in many parts of the universe. So, they used this ratio to extrapolate the amount of hydrogen present in these early galaxies.

A 10-billion-year-old galaxy was made of about 44 percent cold interstellar gas by mass, while an 8-billion-year-old one was about 34 percent. This is three to 10 times more hydrogen than today’s giant galaxies.

The study also showed the old galaxies drew in fuel from their surrounding environment in order to keep up the frantic pace of star formation, Noeske said.

Future research should look at a larger number of galaxies and find a way to measure smaller galaxies, said astronomer Dawn Erb of the University of California, Santa Barbara, who was not involved in the study.

“This is just the tail end of the population of the normal galaxies, just the biggest and most massive ones,” she said. “We just can’t see the normal ones, because they’re too faint.”

To do that, the team will need even-more-sensitive equipment, which they will get when the ALMA observatory in Chile comes online in 2012. “That’s going to be the next big step,” Erb said.

Awakening Sun

Written by XARIUSOUND. Posted on February 9, 2010. Filed under Research, Science. Tagged astronomy, electroreceptor, pulsating effect, radio bursts, solar flares, space, spatiality, stars, Sun. No comments.

As the sun emerges from a long lull in activity, the star’s emissions in the radio band of the spectrum have also picked up. And from a shed on three acres of land outside Santa Fe, New Mexico, amateur radio astronomer Thomas Ashcraft is making recordings of them available for download.

“The Sun has become hyper-dynamic the past few days,” Ashcraft wrote on his website Sunday, along with links to four “specimens” of radio bursts, as he calls them.

The sun is crackling with solar flares now as a very large sunspot continues to circle our star. The recent solar activity almost assuredly signals the end of the solar minimum. Only 5 percent of the days in 2010 have seen a blank sun. In 2008 and 2009, more than 70 percent of the days had no sunspot activity.

Not all bursts sound the same, though. Another kind, Type V, is generally shorter and sharper. They happen to be Ashcraft’s favorites.

“I like that one because they are very strong and very fast,” Ashcraft told Wired.com. “They are only short lived, only a minute or two minutes. You can get a rush out of it. You can get high off of it. You can trip on it a little bit.”

The physics of solar radio emissions are quite complicated, but Ashcraft just likes to listen to the radio static out in the shed on his property. It gives him a feel for what the sun is doing, he said. He held up the phone to his speakers where the standard hiss of the radio, speckled by cosmic background radiation, constantly plays.

“I have that playing at a low level. I’m able to hear when there are sudden fluctuations,” Ashcraft said. “That makes me hypersensitive to the sun. I consider my antennas, which are mostly dipole antennas, I consider them my hyperextended nervous systems, so I can feel subtle solar movements.”

When he processes the recordings, Ashcraft likes to track one frequency (say, 21 megahertz) in one channel and another (say, 24 megahertz) in the other channel. It tends to give his specimens what he calls “spatiality” and a kind of pulsating effect. That’s because he isn’t just trying to record the sun, he’s trying to make it into something with which people can connect.

“I sort of see it as a possible musical form of the future. You know? An energetic form,” Ashcraft said. “Maybe the word isn’t even art anymore, it’s almost nutritional to the nervous system in a way that I don’t know about, but I’m groping towards, kind of as an artist.”

After almost 20 years of studying the sun, Ashcraft said his view of being a human has actually changed.

“I’m very conscious of myself as an organism, an electroreceptor sensing the sun,” Ashcroft said. “It’s human, but the human is a subset of being an organism.”