Showing posts with label WISE. Show all posts
Showing posts with label WISE. Show all posts

Thursday, February 7, 2013

WISE IMAGE OF ORION NEBULA



FROM: NASA

The Orion nebula is featured in this sweeping image from NASA's Wide-field Infrared Survey Explorer, or WISE. The constellation of Orion is prominent in the evening sky throughout the world from about December through April of each year. The nebula (also catalogued as Messier 42) is located in the sword of Orion, hanging from his famous belt of three stars. The star cluster embedded in the nebula is visible to the unaided human eye as a single star, with some fuzziness apparent to the most keen-eyed observers. Because of its prominence, cultures all around the world have given special significance to Orion. The Maya of Mesoamerica envision the lower portion of Orion, his belt and feet (the stars Saiph and Rigel), as being the hearthstones of creation, similar to the triangular three-stone hearth that is at the center of all traditional Maya homes. The Orion nebula, lying at the center of the triangle, is interpreted by the Maya as the cosmic fire of creation surrounded by smoke.

This metaphor of a cosmic fire of creation is apt. The Orion nebula is an enormous cloud of dust and gas where vast numbers of new stars are being forged. It is one of the closest sites of star formation to Earth and therefore provides astronomers with the best view of stellar birth in action. Many other telescopes have been used to study the nebula in detail, finding wonders such as planet-forming disks forming around newly forming stars. WISE was an all-sky survey giving it the ability to see these sites of star formation in a larger context. This view spans more than six times the width of the full moon, covering a region nearly 100 light-years across. In it, we see the Orion nebula surrounded by large amounts of interstellar dust, colored green.

Astronomers now realize that the Orion nebula is part of the larger Orion molecular cloud complex, which also includes the Flame nebula. This complex in our Milky Way galaxy is actively making new stars. It is filled with dust warmed by the light of the new stars within, making the dust glow in infrared light.

Color in this image represents specific infrared wavelengths. Blue represents light emitted at 3.4-micron wavelengths and cyan (blue-green) represents 4.6 microns, both of which come mainly from hot stars. Relatively cooler objects, such as the dust of the nebulae, appear green and red. Green represents 12-micron light and red represents 22-micron light. Image Credit: NASA/JPL-Caltech
/UCLA

Saturday, July 28, 2012

NASA SHOWS OFF FLAME NEBULA


FROM:  NASA
The Flame Nebula sits on the eastern hip of Orion the Hunter, a constellation most easily visible in the northern hemisphere during winter evenings. This view of the nebula was taken by WISE, NASA's Wide-field Infrared Survey Explorer. This image shows a vast cloud of gas and dust where new stars are being born. Three familiar nebulae are visible in the central region: the Flame Nebula, the Horsehead Nebula and NGC 2023. The Flame Nebula is the brightest and largest in the image. It is lit by a star inside it that is 20 times the mass of the sun and would be as bright to our eyes as the other stars in Orion's belt if it weren't for all the surrounding dust, which makes it appear 4 billion times dimmer than it actually is. Image Credit: NASA/JPL-Caltech/UCLA

Monday, April 16, 2012

LOOKING FOR BLACK HOLES CALLED BLAZARS

FROM:  NASA
WASHINGTON -- Astronomers are actively hunting a class of supermassive
black holes throughout the universe called blazars thanks to data
collected by NASA's Wide-field Infrared Survey Explorer (WISE). The
mission has revealed more than 200 blazars and has the potential to
find thousands more.

Blazars are among the most energetic objects in the universe. They
consist of supermassive black holes actively "feeding," or pulling
matter onto them, at the cores of giant galaxies. As the matter is
dragged toward the supermassive hole, some of the energy is released
in the form of jets traveling at nearly the speed of light. Blazars
are unique because their jets are pointed directly at us.

"Blazars are extremely rare because it's not too often that a
supermassive black hole's jet happens to point towards Earth," said
Franceso Massaro of the Kavli Institute for Particle Astrophysics and
Cosmology near Palo Alto, Calif., and principal investigator of the
research, published in a series of papers in the Astrophysical
Journal. "We came up with a crazy idea to use WISE's infrared
observations, which are typically associated with lower-energy
phenomena, to spot high-energy blazars, and it worked better than we
hoped."

The findings ultimately will help researchers understand the extreme
physics behind super-fast jets and the evolution of supermassive
black holes in the early universe.

WISE surveyed the entire celestial sky in infrared light in 2010,
creating a catalog of hundreds of millions of objects of all types.
Its first batch of data was released to the larger astronomy
community in April 2011 and the full-sky data were released last
month.

Massaro and his team used the first batch of data, covering more than
one-half the sky, to test their idea that WISE could identify
blazars. Astronomers often use infrared data to look for the weak
heat signatures of cooler objects. Blazars are not cool; they are
scorching hot and glow with the highest-energy type of light, called
gamma rays. However, they also give off a specific infrared signature
when particles in their jets are accelerated to almost the speed of
light.

One of the reasons the team wants to find new blazars is to help
identify mysterious spots in the sky sizzling with high-energy gamma
rays, many of which are suspected to be blazars. NASA's Fermi mission
has identified hundreds of these spots, but other telescopes are
needed to narrow in on the source of the gamma rays.

Sifting through the early WISE catalog, the astronomers looked for the
infrared signatures of blazars at the locations of more than 300
gamma-ray sources that remain mysterious. The researchers were able
to show that a little more than half of the sources are most likely
blazars.

"This is a significant step toward unveiling the mystery of the many
bright gamma-ray sources that are still of unknown origin," said
Raffaele D'Abrusco, a co-author of the papers from Harvard
Smithsonian Center for Astrophysics in Cambridge, Mass. "WISE's
infrared vision is actually helping us understand what's happening in
the gamma-ray sky."

The team also used WISE images to identify more than 50 additional
blazar candidates and observed more than 1,000 previously discovered
blazars. According to Massaro, the new technique, when applied
directly to WISE's full-sky catalog, has the potential to uncover
thousands more.

"We had no idea when we were building WISE that it would turn out to
yield a blazar gold mine," said Peter Eisenhardt, WISE project
scientist at NASA's Jet Propulsion Laboratory (JPL) in Pasadena,
Calif., who is not associated with the new studies. "That's the
beauty of an all-sky survey. You can explore the nature of just about
any phenomenon in the universe."  
                                               

Search This Blog

Translate

White House.gov Press Office Feed