This false-color image shows infrared (red), optical (green), and X-ray (blue) views of the large star-forming complex N51. The warm ionized gas is shown in green, the hot ionized gas is in blue, and the proto-stars are primarily in red. This color image reveals the relative position of the expanding shell N51D and the recently formed proto-stars, allowing astronomers to determine whether the star formation is triggered by pressure from hot gas or by compression by a passing shock wave. The infrared image was taken with the Spitzer Space Telescope’s Infrared Array Camera (IRAC) at a wavelength of 8 microns. The optical image of hydrogen emission was taken as part of the Magellanic Cloud Emission-Line Survey (MCELS) with the Curtis-Schmidt Telescope at Cerro Tololo Inter-American Observatory in Chile. The X-ray image was taken with the European Space Agency’s satellite, XMM-Newton, using its European Photon Imaging Camera (EPIC) camera.
CHAMPAIGN, Ill. – Black and white reproductions of Vincent van Gogh’s “The Starry Night” lack the beauty and depth of the original oil painting. In a similar fashion, images of stars and galaxies composed of a single wavelength band cannot convey the wealth of information now accessible to astronomers.
In recent years, a number of ground-based optical and radio surveys of the Large and Small Magellanic Clouds – Earth’s nearest neighboring galaxies – have become available. New composite images of optical, radio, infrared, ultraviolet and X-ray wavelengths are giving astronomers at the University of Illinois at Urbana-Champaign a clearer picture of the birth, life and death of massive stars, and their effect on the gas and dust of the interstellar medium surrounding them.
From their birth to their death, massive stars have a tremendous impact on their galactic surroundings. While alive, these stars energize and enrich the interstellar medium with their strong ultraviolet radiation and their fast stellar winds. As they die, shock waves from their death throes inject vast quantities of mechanical energy into the interstellar medium and can lead to the formation of future stars.
“Comparing images at different wavelengths lets us create a more complete picture, rather than seeing only a few features in isolation,” said You-Hua Chu, chair of the astronomy department at Illinois. “Using multi-spectral data sets, we can examine the physical structure of the interstellar medium and study the conditions that lead to star formation.”
This false-color image shows infrared (red), optical (green), and X-ray (blue) views of the N49 supernova remnant. This object, the remains of an exploded star, has million-degree gas in the center, with much cooler gas at the outer parts of the remnant. While astronomers expected that dust particles were generating most of the infrared emission, the study of this object indicates that much of the infrared is instead generated in heated gas. Images forming this composite were taken with NASA’s three Great Observatories. The infrared image was taken with the Spitzer Space Telescope’s Multiband Imaging Photometer for Spitzer (MIPS) at a wavelength of 24 microns. The optical image was taken with the Hubble Space Telescope’s Wide Field Planetary Camera 2 (WFPC2) of hydrogen emission. The X-ray image was taken with the Chandra X-ray Observatory’s Advanced CCD Imaging Spectrometer.
Massive stars interact with the interstellar medium in many ways. Their fast stellar winds and supernova blasts can sweep up the surrounding medium into expanding shells filled with hot gas.
“The expanding shells produce conditions that may start a new wave of star births,” said Robert Gruendl, an Illinois astronomer who uses Spitzer Space Telescope observations to search for proto-stars. “The combination of X-ray, optical and infrared observations allow us to determine whether the pressure of the hot gas or compression by a passing shock wave is responsible for triggering star formation.”
In related work, Illinois astronomer Rosa Williams has added data from a new wavelength regime to her growing database on stellar graveyards in the Magellanic Clouds. Comparing infrared images obtained with the Spitzer Space Telescope, Williams explored the distribution of matter caught in the expanding shells of supernova remnants.
“We expected significant infrared emission to be generated by dust particles,” Williams said. “Instead, most of the emission from these remnants came from heated gas.”
Strong ultraviolet radiation from nearby star-forming regions may have ionized the gas and torn apart the dust particles consisting of hydrocarbon molecules, Williams said. “Other dust particles could have been shattered by shock waves from the supernova.”
To solve the missing dust mystery, Williams said, “We are investigating the nature and amount of dust in regions surrounding the supernova remnants to see whether the deficiency in dust is inherent in the environment or created by the remnant.”
Chu, Gruendl and Williams will present their latest findings at the American Astronomical Society meeting in Washington, D.C., on Wednesday (Jan. 11).
The National Aeronautics and Space Administration funded their work.
Editor’s note:
To reach You-Hua Chu, call 217-333-5535; e-mail: yhchu@uiuc.edu.
To reach Rosa Williams, call 217-244-4209; e-mail: rosanina@uiuc.edu.
To reach Robert Gruendl, call 217-244-4209; e-mail: gruendl@uiuc.edu.
