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Post Info TOPIC: L1157


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Protostar
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Pictures of a baby nestled in a cradle may make you coo, the typical human response to an overdose of cuteness.
But not the kind of baby pictures Leslie Looney and Woojin Kwon are capturing.
Awe is the more likely reaction to the images the University of Illinois researchers have been getting attention for recently and maybe wonder, at the nature of the universe.
The "baby" in this case is a protostar, a big conglomeration of 90 percent hydrogen and 10 percent other gases and dust, with a lot of gravity. It's still millions of years from reaching the critical point where nuclear fusion begins, and it ends up a ball of fire like, say, our sun.

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Posts: 131433
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RE: L1157
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U.S. astronomer Leslie Looney, of the Department of Astronomy at the University of Illinois at Urbana-Champaign, led a group of fellow researchers to this assertion. Their results (A Flattened Protostellar Envelope in Absorption around L1157) were published in the November 5, 2007 issue of Astrophysical Journal Letters.
Co-authors of the paper are former undergraduate student John J. Tobin (now at the University of Michigan) and graduate student Woojin Kwon.
According to the University of Illinois (UIUC) article Astronomers find stellar cradle where planets form, Looneys team found the first definite evidence of a spinning and flattening cloud of gas and dust surrounding a young protostar. The reddish cloud will continue to flatten more as the planet-forming cloud takes on a more and more spherical shape. As this happens the cloud will spin (rotate) faster and faster.

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L

Posts: 131433
Date:
LDN 1157
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LDN 1157 -- Dark Nebula

LDN 1157

(image rotated 90 degrees to the right)

Position (J2000): RA: 20:39:06 Dec: +68:02:13

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L

Posts: 131433
Date:
L1157
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A developing star wrapped in a black cocoon of dust is seen sprouting giant jets in a new image from NASA's Spitzer Space Telescope.
The stellar portrait, seen in infrared light, offers the first glimpse at a very early stage in the life of an embryonic sun-like star -- a time when the star's natal envelope is beginning to flatten and collapse, and streams of gas are escaping. The observations will ultimately help astronomers better understand how stars and their planets form.

"This is the first time we've clearly seen a flattened envelope around a forming star. Some theories had predicted that envelopes flatten as they collapse onto their stars and surrounding planet-forming disks, but we hadn't seen any strong evidence of this until now" - Leslie Looney of the University of Illinois at Urbana-Champaign, lead author of a study about the star, called L1157, appearing Dec. 1 in Astrophysical Journal Letters.

L_1157
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Credit: NASA/JPL-Caltech/UIUC

Position (J2000): RA: 20:39:06 Dec: +68:02:13

Stars are born out of thick clouds, or envelopes, of gas and dust that condense and collapse inward. As a star grows and feeds off the envelope, it spins faster and faster like a twirling ice skater. A disk of planet-forming material begins to take shape in orbit around the star, and jets of gas shoot up from above and below the disk to relieve the star's accumulating pressure. Eventually, the original envelope falls onto the spinning disk, and the jets slow to a stop.
The regions where all the action takes place are dark and dusty, letting little visible light escape. For example, the embryonic star L1157 appears black in visible-light views. Spitzer's infrared view of the star, on the other hand, penetrates the dusty haze, giving us a rare look at what our own solar system might have looked like when it was very young.
The bipolar jets shooting away from L1157 are enormous; light itself would take about nine months to travel the length of one jet. The colour white shows the hottest parts of the jets, with temperatures around 100 degrees Celsius (212 degrees Fahrenheit). Most of the material in the jets, seen in orange, is roughly zero degrees on the Celsius and Fahrenheit scales.
The flattened envelope around the fledgling star is perpendicular to the jets and appears deep black. This is because it is so thick with dust that even infrared light cannot escape. The envelope is big enough to engulf the equivalent of tens of thousands of mature solar systems similar to our own, while the planet-forming disk tucked inside cannot be seen in this photo -- it is smaller than a pixel.
L1157 is located about 800 light-years away in the constellation Cepheus. It is roughly 10,000 years old, and, according to astronomers' estimates, will ignite to become a full-fledged star about the mass of our sun in a million years or so.

"Taking baby pictures of stars is not easy to do. Now that we have a good picture, we can begin to ask questions about whether this star system and its potential planets will grow up to become like ours" - Leslie Looney.

Other authors of this study include John J. Tobin of the University of Michigan, Ann Arbor, and Woojin Kwan of the University of Illinois.
NASA's Jet Propulsion Laboratory, Pasadena, California, manages the Spitzer Space Telescope mission for NASA's Science Mission Directorate, Washington. Science operations are conducted at the Spitzer Science Centre at the California Institute of Technology, also in Pasadena. Caltech manages JPL for NASA. Spitzer's infrared array camera, which took the new picture of L1157, was built by NASA's Goddard Space Flight Centre, Greenbelt, Md. The instrument's principal investigator is Giovanni Fazio of the Harvard-Smithsonian Centre for Astrophysics.

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