Sun Storm: A Coronal Mass Ejection

Credit: SOHO Consortium, ESA, NASA

Explanation: Late last month another erupting filament lifted off the active solar surface and blasted this enormous bubble of magnetic plasma into space. Direct light from the sun is blocked in this picture of the event with the sun’s relative position and size indicated by a white half circle at bottom center. The field of view extends 2 million kilometers or more from the solar surface. While hints of these explosive events, called coronal mass ejections or CMEs, were discovered by spacecraft in the early 70s this dramatic image is part of a detailed record of this CME’s development from the presently operating SOlar and Heliospheric Observatory (SOHO) spacecraft. Near the minimum of the solar activity cycle CMEs occur about once a week, but as we approach solar maximum rates of two or more per day are anticipated. Though this CME was clearly not headed for Earth, strong CMEs are seen to profoundly influence space weather, and those directed toward our planet and can have serious effects.

Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (USRA)

The Pipe Dark Nebula

Credit & Copyright: Jerry Lodriguss

Explanation: The dark nebula predominant at the lower left of the above photograph is known as the Pipe Nebula. The dark clouds, suggestively shaped like smoke rising from a pipe, are caused by absorption of background starlight by dust. These dust clouds can be traced all the way to the Rho Ophiuchi nebular clouds on the right. The brightest star in the field is Antares. Many types of nebula are highlighted here: the red are emission nebula, the blue are reflection nebula, and the dark are absorption nebula. This picture has been digitally enhanced.

Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (USRA)

The Sombrero Galaxy from VLT

Credit: Peter Barthel (Kapteyn Inst.) et al., FORS1, VLT ANTU, ESO

Explanation: Why does the Sombrero Galaxy look like a hat? Reasons include the Sombrero’s unusually large and extended central bulge of stars, and dark prominent dust lanes that appear in a disk that we see nearly edge-on. Billions of old stars cause the diffuse glow of the extended central bulge. Close inspection of the bulge in the above photograph shows many points of light that are actually globular clusters. M104’s spectacular dust rings harbor many younger and brighter stars, and show intricate details astronomers don’t yet fully understand. The very center of the Sombrero glows across the electromagnetic spectrum, and is thought to house a large black hole. Light from the Sombrero Galaxy can be seen with a small telescope towards the constellation of Virgo.

Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (USRA)

Neighboring Galaxy: The Large Magellanic Cloud

Credit & Copyright: AURA/ NOAO/ NSF

Explanation: The brightest galaxy visible from our own Milky Way Galaxy is the Large Magellanic Cloud (LMC). Visible predominantly from Earth’s Southern Hemisphere, the LMC is the second closest galaxy, neighbor to the Small Magellanic Cloud, and one of eleven known dwarf galaxies that orbit our Milky Way Galaxy. The LMC is an irregular galaxy composed of a bar of older red stars, clouds of younger blue stars, and a bright red star forming region visible near the top of the above image called the Tarantula Nebula. The brightest supernova of modern times, SN1987A, occurred in the LMC.

Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (USRA)

M106: A Spiral Galaxy with a Strange Core

Credit: Ron & Beth Sharer, Steven White, AOP, KPNO, NOAO, NSF

Explanation: What’s happening at the center of spiral galaxy M106? A swirling disk of stars and gas, M106’s appearance is dominated by two bright spiral arms and dark dust lanes near the nucleus. Bright newly formed stars near their outer tips distinguish the spiral arms in the above photograph. The core of M106 glows brightly in radio waves and X-rays where twin jets have been found running the length of the galaxy. An unusual central glow makes M106 one of the closest examples of the Seyfert class of galaxies, where vast amounts of glowing gas are thought to be falling into a central massive black hole. M106, also designated NGC 4258, is a relatively close 25 million light years away, spans 30 thousand light years across, and can be seen with a small telescope towards the constellation of Canes Venatici.

Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (USRA)

Southwest Mercury

Credit: Mariner 10, NASA

Explanation: The planet Mercury resembles a moon. Mercury’s old surface is heavily cratered like many moons. Mercury is larger than most moons but smaller than Jupiter’s moon Ganymede and Saturn’s moon Titan. Mercury is much denser and more massive than any moon, though, because it is made mostly of iron. In fact, the Earth is the only planet more dense. A visitor to Mercury’s surface would see some strange sights. Because Mercury rotates exactly three times every two orbits around the Sun, and because Mercury’s orbit is so elliptical, a visitor to Mercury might see the Sun rise, stop in the sky, go back toward the rising horizon, stop again, and then set quickly over the other horizon. From Earth, Mercury’s proximity to the Sun cause it to be visible only for a short time just after sunset or just before sunrise.

Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (USRA)

Galaxy Wars: M81 Versus M82

Credit & Copyright: Robert Gendler

Explanation: In the left corner, wearing a red nucleus surrounded by blue spiral arms, is M81. In the right corner, sporting light stars and dark dust lanes, is M82. These two mammoth galaxies have been locked in gravitational combat for the past billion years. The gravity from each galaxy dramatically affects the other during each hundred million-year pass. Last go-round, M82’s gravity likely raised circulating density waves rippling around M81 resulting in the richness of M81’s spiral arms. M81, though, left M82 a messy pulp of exploded stars and colliding gas so violent it emits bright X-rays. In both galaxies, colliding gas has created a recent abundance of bright new stars. In a few billion years only one galaxy will remain.

Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (USRA)

Colorful Clouds Of Carina

Credit: Hubble Heritage Team (AURA/ STScI), NASA

Explanation: Tumultuous clouds of the Carina Nebula, 8000 light-years away, glow in planet Earth’s southern sky. Striking and detailed, this close-up of a portion of the famous nebula is a combination of exposures through six different filters taken with the Hubble Space Telescope’s Wide Field Planetary Camera 2 in April of 1999. Dramatic dark dust knots and complex features revealed are sculpted by the winds and radiation of Carina’s massive and energetic stars. But how were this picture’s colors generated? Astronomical images produced from Hubble Space Telescope data can be composed of exposures made using relatively narrow filters which don’t match the color responses of the human eye. Some of the filters even transmit wavelengths of light outside the visible spectrum. Exposures made with different narrow filters, as in this case, are translated to a visible color where shorter wavelengths are assigned bluer and longer wavelengths assigned redder colors. This color scheme represents a “chromatically ordered” way of presenting the data rather than a natural color image.

Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (USRA)

The Eskimo Nebula from the Newly Fixed Hubble

Credit: Andrew Fruchter (STScI) et al., WFPC2, HST, NASA

Explanation: In 1787, astronomer William Herschel discovered the Eskimo Nebula. From the ground, NGC 2392 resembles a person’s head surrounded by a parka hood. In 2000, just after being fixed, theHubble Space Telescope imaged the Eskimo Nebula. From space, the nebula displays gas clouds so complex they are not fully understood. The Eskimo Nebula is clearly a planetary nebula, and the gas seen above composed the outer layers of a Sun-like star only 10,000 years ago. The inner filaments visible above are being ejected by strong wind of particles from the central star. The outer disk contains unusual light-year long orange filaments. The Eskimo Nebula lies about 5000 light-years away and is visible with a small telescope in the constellation of Gemini.

Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (USRA)

X For Andromeda

Credit: S. Murray, M. Garcia, et al., (CfA) SAO, CXO, NASA

Explanation: A big beautiful spiral galaxy 2 million light-years away, Andromeda (M31) has long been touted as an analog to the Milky Way, a distant mirror of our own galaxy. The popular 1960s British sci-fi series, A For Andromeda, even postulated that it was home to another technological civilization that communicated with us. Using the newly unleashed observing power of the orbiting Chandra X-ray telescope, astronomers have now imaged the center of our near-twin island universe, finding evidence for an object so bizarre it would have impressed many 60s science fiction writers (and readers). Like the Milky Way, Andromeda’s galactic center appears to harbor an X-ray source characteristic of a black hole of a million or more solar masses. Seen above, the false-color X-ray picture shows a number of X-ray sources, likely X-ray binary stars, within Andromeda’s central region as yellowish dots. The blue source located right at the galaxy’s center is coincident with the position of the suspected massive black hole. While the X-rays are produced as material falls into the black hole and heats up, estimates from the X-ray data show Andromeda’s central source to be surprisingly cool – only a million degrees or so compared to the tens of millions of degrees indicated for Andromeda’s X-ray binaries.

Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (USRA)