A radio and infrared wave panorama of a section of the Milky Way in the constellations of Scutum and Aquila. Normal stars show up as the myriad of aqua-white points. Radiation from the newborn stars heats surrounding dust into infrared temperatures (in violet), while the ultraviolet light from these stars separates electrons from hydrogen atoms, and gives off radio waves (in red). More mature stars have destroyed nearby dust, leaving red cores surrounded by aqua, then violet, shells as the temperature drops far from the stars. Massive stars have died in titanic explosions and blasted their gas light years into space at thousands of miles per second, leaving blast arcs (in red). The diffuse infrared glow (violet) comes from the tiny dust particles scattered through space.
Across the Milky Way (gold version)
A radio and infrared wave panorama of a section of the Milky Way in the constellations of Scutum and Aquila. Normal stars show up as the myriad of yellow-white points. Radiation from the newborn stars heats surrounding dust into infrared temperatures (in gold), while the ultraviolet light from these stars separates electrons from hydrogen atoms, and gives off radio waves (in red). More mature stars have destroyed nearby dust, leaving red cores surrounded by yellow, then gold, shells as the temperature drops far from the stars. Massive stars have died in titanic explosions and blasted their gas light years into space at thousands of miles per second, leaving blast arcs (in red). The diffuse infrared glow (gold) comes from the tiny dust particles scattered through space.
The Expansion of Supernova 1993j
SN 1993J was discovered March 28, 1993, by Francisco Garcia Diaz, an amateur astronomer in Lugo, Spain, using a 10-inch Newtonian telescope. Located in M81, a spiral galaxy in the constellation Ursa Major, this supernova is 11 million light-years from Earth. By observing at regular intervals with the Very Long Baseline Array (VLBA), the Very large Array (VLA), and various tracking stations around the world, we have produced this sequence of images showing a shell-like radio structure that has expanded for seven years with circular symmetry. At first the expansion rate was nearly 10,000 miles per second, but it has decelerated since, and had slowed to less than 6,000 miles per second by February, 2000. In this false color image, blue is faintest and red brightest.
Stars Forming in our Galaxy’s Heart
The Galactic Center and the surrounding Central Molecular Zone make up the most active star formation region in the Milky Way. Regions of molecular hydrogen (purple), seen by the Very Large Array (VLA), are illuminated by hot, massive stars, supernova remnants, and synchrotron emission. The Caltech Submillimeter Observatory observed cold (20-30 K) dust associated with molecular gas (orange). Some of this material will form stars within in the next few million years; the remainder will be blown away. The diffuse cyan and colored star images are from the Spitzer Space Observatory’s Infrared Array Camera. The cyan is primarily emission from stars, the point sources, and from polycyclic aromatic hydrocarbons (PAHs), the diffuse component.
W50: The Manatee Nebula
This enormous W50 cloud, visible only in radio waves, formed when a giant star, 18,000 light years away in the constellation of Aquila, exploded around twenty thousand years ago. The remaining black hole feeds on gas it collects from a very close companion star. Its gas disk and powerful magnetic field lines act like an enormous railroad system. It snags charged particles and channels them outward as powerful jets traveling at nearly the speed of light. This system shines brightly in both radio waves and X-rays and is known collectively as the SS433 microquasar. Over time, the microquasar’s wobbling jets have punched corkscrew bulges on either side of W50, seen here in this image from the Very Large Array (VLA).
Starbursting M82
The Cigar Galaxy, M82, is experiencing a furious phase of star formation. Clouds of gas and dust are collapsing into stars across the center of this galaxy, and the Very Large Array has mapped them here as bright points. Streaming out from many of the star-forming regions are the jets from giant young stars pushing charged, excess gas up and out of their accretion disks. This VLA radio image (tinted green) has been placed on top of an optical image from the Hubble Space Telescope.