Pictures, articles, and space junk.

click photos for sources.


this girl created this tiny universe. and this girl helps run it.
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Galaxy Zoo Catalogs the Universe You, too, can Zoo. The Galaxy Zoo project has been enabling citizen scientists — inquisitive people like yourself armed with only a web browser— to sort through the universe. Specifically, after a brief training session, volunteers are asked to use the superior image-processing power of their minds to classify and measure properties of galaxies in the vast Sloan Digital Sky Survey. In its two short years of existence, millions of galaxies have already been inspected by thousands of enthusiastic volunteers. Using Galaxy Zoo data, for example, the universe has been discovered to create no preferred spin direction, an unusual and unclassified object was found that is still being investigated, and a whole class of small galaxies dubbed Green Peas were uncovered where star formation occurs at an extraordinary high rate. Further, the Galaxy Zoo may be setting a precedent for a new type of scientific inquiry where the web helps collect, focus and coordinate human and machine intelligence. Pictured above, a group of vibrant mergers found by Zooites demonstrates the diverse zoo-like nature of many interacting galaxies in the universe.

Galaxy Zoo Catalogs the Universe

You, too, can Zoo. The Galaxy Zoo project has been enabling citizen scientists — inquisitive people like yourself armed with only a web browser— to sort through the universe. Specifically, after a brief training session, volunteers are asked to use the superior image-processing power of their minds to classify and measure properties of galaxies in the vast Sloan Digital Sky Survey. In its two short years of existence, millions of galaxies have already been inspected by thousands of enthusiastic volunteers. Using Galaxy Zoo data, for example, the universe has been discovered to create no preferred spin direction, an unusual and unclassified object was found that is still being investigated, and a whole class of small galaxies dubbed Green Peas were uncovered where star formation occurs at an extraordinary high rate. Further, the Galaxy Zoo may be setting a precedent for a new type of scientific inquiry where the web helps collect, focus and coordinate human and machine intelligence. Pictured above, a group of vibrant mergers found by Zooites demonstrates the diverse zoo-like nature of many interacting galaxies in the universe.

Map of the near by Universe. The clustering pattern of about 100,000 nearby galaxies, revealed by the 6dF Galaxy Survey. Each galaxy is shown as a dot. The galaxy we live in is at the centre of the pattern. Credit: Dr Chris Fluke, Centre for Astrophysics and Supercomputing, Swinburne University of Technology.

Map of the near by Universe.

The clustering pattern of about 100,000 nearby galaxies, revealed by the 6dF Galaxy Survey. Each galaxy is shown as a dot. The galaxy we live in is at the centre of the pattern. Credit: Dr Chris Fluke, Centre for Astrophysics and Supercomputing, Swinburne University of Technology.

This very deep image taken with the NASA/ESA Hubble Space Telescope shows the spiral galaxy NGC 4921 along with a spectacular backdrop of more distant galaxies. It was created from a total of 80 separate pictures through yellow and near-infrared filters.

This very deep image taken with the NASA/ESA Hubble Space Telescope shows the spiral galaxy NGC 4921 along with a spectacular backdrop of more distant galaxies. It was created from a total of 80 separate pictures through yellow and near-infrared filters.

What is your favorite galaxy shape?

Im a fan of spiral barred galaxies (particularly SBa and SBb).

Here’s a hubble tuning fork diagram to give you an idea of the shapes if you have none. :]

M81 and M82 Galaxies

M81 and M82 Galaxies

Hubble Illuminates Cluster of Diverse Galaxies

Hubble Illuminates Cluster of Diverse Galaxies

Researchers discover less ordinary matter than predicted

The smallest dwarf satellite galaxies have only about 1 percent of the normal matter scientists expect.

January 7, 2010 
An international team of scientists, led by University of Maryland astronomer Stacy McGaugh, has found that individual galactic objects have less ordinary matter, relative to dark matter, than does the universe as a whole.

McGaugh presented these results, recently published in the Astrophysics Journal electronic version, Wednesday from the American Astronomical Society Meeting in Washington, D.C.

Scientists believe all ordinary matter, the protons and neutrons that make up people, planets, stars, and all that we can see, are a mere fraction — some 17 percent — of the total matter in the universe. The protons & neutrons of ordinary matter are referred to as baryons in particle physics and cosmology.

The remaining 83 percent apparently is the mysterious “dark matter,” the existence of which is inferred largely from its gravitational pull on visible matter. Dark matter, explains McGaugh, “is presumed to be some new form of non-baryonic particle — the stuff scientists hope the Large Hadron Collider at CERN will create in high-energy collisions between protons.”

McGaugh and his colleagues posed the question of whether the “universal” ratio of baryonic matter to dark matter holds on the scales of individual structures like galaxies.

“One would expect galaxies and clusters of galaxies to be made of the same stuff as the universe as a whole, so if you make an accounting of the normal matter in each object, and its total mass, you ought to get the same 17 percent fraction,” he says. “However, our work shows that individual objects have less ordinary matter, relative to dark matter, than you would expect from the cosmic mix; sometimes a lot less!”

Just how much less depends systematically on scale, according to the researchers. The smaller an object, the further its ratio of ordinary matter to dark matter is from the cosmic mix. McGaugh says their work indicates that the largest bound structures, rich clusters of galaxies, have 14 percent of ordinary baryonic matter, close to the expected 17 percent.

“As we looked at smaller objects — individual galaxies and satellite galaxies — the normal matter content gets steadily less,” he says. “By the time we reach the smallest dwarf satellite galaxies, the content of normal matter is only about 1 percent of what it should be. [Such galaxies’ baryon content is about 0.2 percent instead of 17 percent.] The variation of the baryon content is very systematic with scale. The smaller the galaxy, the smaller is its ratio of normal matter to dark matter. Put another way, the smallest galaxies are very dark matter dominated.

“This raises an obvious question,” McGaugh says. “Where are all these missing baryons? The short answer is, we don’t know. There are various lines of speculation, most of which are either easily dismissed or are untestable. So, for now, this is a problem without an obvious solution.”

Some 17 percent of the material in a galaxy cluster, such as Abell 1060 in Hydra, seen here, consists of ordinary matter (the other material being dark matter). But scientists have discovered that individual dwarf galaxies are only some 0.2 percent ordinary matter.

Some 17 percent of the material in a galaxy cluster, such as Abell 1060 in Hydra, seen here, consists of ordinary matter (the other material being dark matter). But scientists have discovered that individual dwarf galaxies are only some 0.2 percent ordinary matter.

IC 4970 and NGC 6872

IC 4970 and NGC 6872