The star-forming region NGC 1333 contains dozens of new stars like the Sun but less than 1 million years old. Spitzer's IRAC camera reveals those stars, as well as warm dust glowing red and bright green shock fronts in this colour-coded infrared image. Its proximity to Earth and young age make NGC 1333 an ideal laboratory for studying low-mass star formation.
Expand (144kb, 1024 x 885) Image credit: NASA/JPL-Caltech/R. Gutermuth & A. Porras (CfA)
In this Spitzer image, the location of IRAS 4A is marked with an arrow. Nothing is visible at this location; IRAS 4A remains cloaked in its dusty cocoon so infrared emission is minimal. The Submillimeter Array can study emission from the dust itself. By examining the polarisation of that emission, the shape of the magnetic field is revealed.
Long predicted by theory, the Smithsonian's Submillimeter Array has found the first conclusive evidence of an hourglass-shaped magnetic field in a star formation region. Measurements indicate that material in the interstellar cloud is dense enough to allow it to gravitationally collapse, warping the magnetic field in the process.
Astronomers Josep Girart (Institute of Space Studies of Catalonia, Spanish National Research Council), Ramprasad Rao (Institute of Astronomy and Astrophysics, Academia Sinica), and Dan Marrone (Harvard-Smithsonian Center for Astrophysics) studied the protostellar system designated NGC 1333 IRAS 4A. This system of two protostars is located approximately 980 light-years from Earth in the direction of the constellation Perseus. They reported their findings in the August 11 issue of the journal Science.
The protostellar system NGC 1333 IRAS 4A is the first textbook example of an hourglass-shaped magnetic field (shown by dashed red lines on this colour-coded submillimeter image). The pear-shaped green and red region marks the locations of two still-forming stars. Gravity is pulling the gas and dust of this interstellar cloud clump inward, warping the magnetic field in the process. Taken with the Smithsonian's Submillimeter Array, this image is about 7 arcseconds on a side, which translates to a physical size of 2,700 astronomical units (using a distance to the system of 980 light-years). Image credit: J. Girart (CSIC-IEEC), R. Rao (ASIAA) and D. Marrone (CfA)
"We selected this system because previous work had offered tantalizing hints of an hourglass-shaped magnetic field. The Submillimeter Array offered the resolution and sensitivity we needed to confirm it" - Dan Marrone.
NGC 1333 IRAS 4A is part of the Perseus molecular cloud complex - a collection of gas and dust holding as much mass as 130,000 suns. This region is actively forming stars. Its proximity to Earth and young age make the Perseus complex an ideal laboratory for studying star formation. Theorists predict that collapsing molecular cloud cores - the seeds of star formation - have to overcome the support provided by their magnetic field in order to form stars. In the process, the competition between gravity pulling inward and magnetic pressure pushing outward was expected to produce a warped, hourglass pattern to the magnetic field within these collapsed cores. Using the Array, Marrone and his colleagues observed dust emission from IRAS 4A. Because the magnetic field aligns the dust grains in the cloud core, the team could measure the magnetic field's geometry and estimate its strength by measuring the polarization of the dust emission.
"With the special polarisation capabilities of the SMA we see the shape of the field directly. This is the first textbook example of theoretically predicted magnetic structure" - Ramprasad Rao.
The data indicate that, in the case of IRAS 4A, magnetic pressure is more influential than turbulence in slowing star formation within the cloud core. The same likely is true for similar cloud cores elsewhere. Despite the moderating influence of the magnetic field, IRAS 4A is dense enough for gravitational collapse to continue. Approximately a million years in the future, two sunlike stars will shine where only a dust-cloaked cocoon lies today.
Source Harvard-Smithsonian Centre for Astrophysics