Imagine the Universe News - 26 April 2005
Newly Seen Force In Star Formation May Help Gravity
|26 April 2005|
This near infrared image comes from the R Corona Australis star-forming region, about 500 light years from Earth. Many protostars (reddish) and young stars (bright white) are seen here.
(Credit: UH88/Nedachi et al.)
The observation, made primarily with the European Space Agency's XMM-Newton observatory, suggests that some unrealized, energetic process -- likely related to magnetic fields -- is superheating the surface of the cloud core, nudging the cloud ever closer to becoming a star.
The observation marks the first clear detection of X-rays from a precursor to a star, called a Class 0 protostar. The surprise is that these stars are cold, and this detection of X-rays is far earlier in a star's evolution than most experts in this field thought possible. X-rays are produced in space by processes that release a lot of energy and heat. The detection of X-rays from such a cold object reveals that matter is falling toward the protostar core 10 times faster than expected from gravity alone.
"We are seeing star formation at its embryonic stage," said Dr. Kenji Hamaguchi, a NASA-funded researcher at NASA Goddard Space Flight Center in Greenbelt, Md., lead author on a report in The Astrophysical Journal. "Previous observations have captured the shape of such gas clouds but have never been able to peer inside. The detection of X-rays this early indicates that gravity alone is not the only force shaping young stars."
Supporting data came from NASA's Chandra X-ray Observatory, Japan's Subaru telescope in Hawaii, and the University of Hawaii 88-inch telescope. Hamaguchi's team discovered X-rays from a Class 0 protostar in the R Corona Australis star-forming region, about 500 light years from Earth.
Class 0 is the youngest class of protostellar object, about 10,000 to 100,000 years into the star forming process. The cloud temperature is about 400 degrees below zero Fahrenheit (minus 240 Celsius). After a few million years, nuclear fusion ignites at the center of the collapsing protostellar cloud, and a new star is formed.
The team speculates that magnetic fields in the spinning protostar core accelerate infalling matter to high speeds, producing high temperatures and X-rays in the process. These X- rays can penetrate the dusty region to reveal the core.
"This is no gentle freefall of gas," said Dr. Michael Corcoran of Universities Space Research Assocication and NASA/GSFC, a co-author on the report. "The X-ray emission shows that forces appear to be accelerating matter to high speeds, heating regions of this cold gas cloud to 100 million degrees Fahrenheit. The X-ray emission from the core gives us a window to probe the hidden processes by which cold gas clouds collapse to stars."
Hamaguchi likened the generation of X-rays in the Class 0 protostar to what happens during solar flares on our Sun. The solar surface has lots of magnetic loops, which sometimes get tangled and release large amounts of energy.� This energy can accelerate electrically-charged particles (electrons and ionized atoms) to velocities of 7 million miles an hour. The particles smash against the solar surface and create X-rays. Similarly tangled magnetic fields might be responsible for X-rays observed by Hamaguchi and his collaborators.
A close up comparison of the protostar in X-ray and infrared light.
(Credit: ESA/XMM/Hamaguchi et al.)
The detection of magnetic fields from an extremely young Class 0 protostar provides a crucial link in understanding the star formation process, because magnetic field loops are believed to play a critical role in moderating the cloud collapse. Only electrically-charged particles, called ions, respond to magnetic fields.� The scientists are not sure where the magnetic fields or ions come from.� However, X-rays will ionize atoms, creating more ions to accelerate through magnetic activity.
The team used XMM-Newton for its powerful light-collecting capability, necessary for this type of observation where so few X-rays penetrate the dusty region, and the exquisite resolving power of Chandra to pinpoint the X-ray source position. The team used the infrared Subaru telescope to determine the protostar's age.
"The age is based on a well-established chart of spectra, or characteristics of the infrared light, as the protostar evolves over the course of a million years," said Ko Nedachi, a doctoral student at the University of Tokyo who led the Subaru observation.
The science team also includes Drs. Rob Petre and Nicholas White of NASA Goddard, Dr. Beate Stelzer of the Astronomy Observatory in Palermo, Italy, and Dr. Naoto Kobayashi of University of Tokyo. Kenji Hamaguchi is funded through the National Research Council; Michael Corcoran is funded through USRA.