Swift Telescope Sees the Pinwheel Galaxy
PSU — The Swift satellite’s Ultraviolet/Optical Telescope (UVOT) has seen first light, capturing an image of the Pinwheel Galaxy, long loved by amateur astronomers as the “perfect” face-on spiral galaxy. The UVOT now remains poised to observe its first gamma-ray burst.
Swift is a NASA-led mission dedicated to the gamma-ray burst mystery. These random and fleeting explosions likely signal the birth of black holes. With the UVOT turned on, Swift now is fully operational. Swift’s two other instruments — the Burst Alert Telescope (BAT) and the X-ray Telescope (XRT) — were turned on over the past several weeks and have been snapping up gamma-ray bursts ever since.
“After many years of effort building the UVOT, it was exciting to point it toward the famous Pinwheel Galaxy, M101,” said Peter Roming, UVOT Lead Scientist at Penn State. “The ultraviolet wavelengths in particular reveal regions of star formation in the galaxy’s wispy spiral arms. But more than a pretty image, this first-light observation is a test of the UVOT’s capabilities.”
Swift’s three telescopes work in unison. The BAT detects gamma-ray bursts and autonomously turns the satellite in seconds to bring the burst within view of the XRT and the UVOT, which provide detailed follow-up observations of the burst afterglow. Although the burst itself is gone within seconds, scientists can study the afterglow for clues about the origin and nature of the burst, much like detectives at a crime scene.
The UVOT serves several important functions. First, it will pinpoint the gamma-ray burst location a few minutes after the BAT detection. The XRT provides a burst position within a 1- to-2-arcsecond range.
The UVOT will provide sub-arcsecond precision, a spot on the sky far smaller than the eye of a needle at arm’s length. This information is then relayed to scientists at observatories around the world so that they can view the afterglow with other telescopes.
As the name applies, the UVOT captures the optical and ultraviolet component of the fading burst afterglow. “The ‘big gun’ optical observatories such as Hubble, Keck, and VLT have provided useful data over the years, but only for the later portion of the afterglow,” said Keith Mason, the U.K. UVOT Lead at University College London’s Mullard Space Science Laboratory.
“The UVOT isn’t as powerful as these observatories, but has the advantage of observing from the very dark skies of space. Moreover, it will start observing the burst afterglow within minutes, as opposed to the day-long or week-long lag times inherent with heavily used observatories. The bulk of the afterglow fades within hours.”
The ultraviolet portion will be particularly revealing, said Roming. “We know nearly nothing about the ultraviolet part of a gamma-ray burst afterglow,” he said. “This is because the atmosphere blocks most ultraviolet rays from reaching telescopes on Earth, and there have been few ultraviolet telescopes in orbit. We simply haven’t yet reached a burst fast enough with a UV telescope.”
The UVOT’s imaging capability will enable scientists to understand the shape of the afterglow as it evolves and fades. The telescope’s spectral capability will enable detailed analysis of the dynamics of the afterglow, such as the temperature, velocity, and direction of material ejected in the explosion.
The UVOT also will help scientists determine the distance to the closer gamma-ray bursts, within a redshift of 4, which corresponds to a distance of about 11 billion light years. The XRT will determine distances to more distant bursts.
Scientists hope to use the UVOT and XRT to observe the afterglow of short bursts, less than two seconds long. Such afterglows have not yet been seen; it is not clear if they fade fast or simply don’t exist. Some scientists think there are at least two kinds of gamma-ray bursts: longer ones (more than two seconds) that generate afterglows and that seem to be caused by massive star explosions, and shorter ones that may be caused by mergers of black holes or neutron stars. The UVOT and XRT will help to rule out various theories and scenarios.
The UVOT is a 30-centimeter telescope with intensified CCD detectors and is similar to an instrument on the European Space Agency’s XMM-Newton mission. The UVOT is as sensitive as a four-meter optical ground-based telescope. The UVOT’s day-to-day observations, however, will look nothing like M101. Distant and faint gamma-ray burst afterglows will appear as tiny smudges of light even to the powerful UVOT. The UVOT is a joint product of Penn State and the Mullard Space Science Laboratory.
Swift is a medium-class explorer mission managed by NASA Goddard. Swift is a NASA mission with participation of the Italian Space Agency and the Particle Physics and Astronomy Research Council in the United Kingdom. It was built in collaboration with national laboratories, universities and international partners, including Penn State University in Pennsylvania, U.S.A.; Los Alamos National Laboratory in New Mexico, U.S.A.; Sonoma State University in California, U.S.A.; the University of Leicester in Leicester, England; the Mullard Space Science Laboratory in Dorking, England; the Brera Observatory of the University of Milan in Italy; and the ASI Science Data Center in Rome, Italy.
M101 is a bright, face-on, spiral galaxy located in the constellation Ursa Major (containing the Big Dipper), about 15 million light years from Earth. These first-light images of the M101 galaxy demonstrate that the UVOT is functioning well in detecting ultraviolet and optical data. The UVOT is now poised on the Swift observatory to add to the limited data now available in optical wavelengths and to capture the first data ever available in ultraviolet wavelengths from an early gamma-ray-burst light curve.
This UVOT image of the pinwheel galaxy M101 is a ‘false-color’ image generated with the UVOT ultraviolet filters. Light from the shortest wavelength ultraviolet filter is represented by blue, with light from the next two shortest wavelength ultraviolet filtersbeing represented by green and red, respectively. This image highlights the star forming regions in the spiral arms, where hot young stars are emitting mostly ultraviolet light.
This UVOT image of the pinwheel galaxy M101 is a ‘false-color’ image generated with the near-UV, the blue, and yellow filters, represented by blue, green, and red, respectively. This image shows more light from the central regions of the galaxy, where older, cooler stars dominate the emission.
Combined Ultraviolet-Optical Image
This UVOT image combines both ultraviolet and visible light from a number of filters. Each filter is sensitive to light of a different color, ranging from ultraviolet light beyond the range of human eyesight through the blue to yellow portion of the visible spectrum. This is a “Ëœfalse-color’ image with the shortest wavelength ultraviolet rays being represented as blue, and the longest visible light wavelengths as red. The image shows that hot young stars are being formed in abundance in M101, especially in the spiral arms of the galaxy, where they show up in ultraviolet light. The central regions of the galaxy have more cool, old stars, which appear “Ëœred’ in the picture. A number of foreground stars, located in our own Galaxy, also reveal themselves by their red color.
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