Infrared view of the center of our galaxy
Galaxies are giant
systems of stars at very great distances
from each other. Galaxies also contain
interstellar material in the form of
diffuse gas and dust particles,
permeated by weak magnetic fields in
which are trapped energetic charged
particles called cosmic rays.
Elliptical galaxies are spheroidal in
shape and have little interstellar
matter; spiral galaxies are highly
flattened rotating discs composed of
interstellar matter and large numbers of
massive stars, as well as the less
massive stars that are also common in
ellipticals. The matter in the disc
forms a spiral pattern, usually with two
spiral arms.
In the nucleus of some galaxies active
sources of relativistic particles
(particles with speeds approaching that
of light) emit radio waves and X-rays as
well as visible light. This phenomenon
is observed in both elliptical and
spiral galaxies; objects called quasars
seem to be extreme forms of such
activity, with luminosities ranging up
to 100 times that of all the stars in
the galaxy. At present the explanation
of the energy source in active galaxies
is uncertain (see
Radio Astronomy).
Theoretical models of galaxies are based on the exchange of matter and energy between stars and interstellar matter. When a galaxy forms, it consists at first entirely of gas, but stars then form from this. From the supernovae occurring among these stars, matter enriched in heavy elements is ejected into space. Thus, interstellar matter is progressively enriched with heavy elements, which then become part of new generations of stars. In ellipticals, the process is largely complete, and little interstellar matter remains. In spirals, however, much interstellar matter remains; in these galaxies the rate of star formation is much higher in the spiral arms than in the core. Apparently, spiral density waves compress interstellar matter to form dark clouds, and these subsequently collapse to form new stars.
Classifying Galaxies - interactive lesson on the Hubble system of classifying galaxies for grades 5-9.
Claudette,
when she was teaching in Florida worked
with the Center for Astrophysics at The
University of California and the Science
Museum of Virginia on this site.
 | The Small Magellanic Cloud (SMC) is an irregular galaxy in orbit about our own Milky Way. |
At a distance of about 200,000 light years, it is one of the Milky Way's nearest neighbours. In fact, it is one of the most distant objects that can be seen with the naked eye.
With a mean declination of approximately -72 degrees, it is best viewed from the Southern Hemisphere. It can be located in the constellation of Tucana and appears as a hazy, light patch in the night sky about 3 degrees across. It looks like a detached piece of the Milky Way.
It forms a pair with the Large Magellanic Cloud (LMC), which is positioned a further 20 degrees to the east.
Since it has a very low surface brightness, it is best viewed from a dark site away from city lights.
| Magellanic
Cloud Picture Collection - the
Magellanic Clouds at different
wavelengths.
| Messier
Catalog: The Small Magellanic Cloud,
SMC | Direct
Project - determining the
distances to nearby galaxies.
| Galaxy
Catalog, The - a collection of
digital images of nearby galaxies.
| Scientific
American: Galaxies Behind the Milky
Way - over a fifth of the
universe is hidden from view,
blocked by dust and stars in the
disk of our galaxy. But over the
past few years, astronomers have
found ways to peek through the murk. |
|
Galaxies
The Shape of Galaxies Galaxies come in three major classes distinguished by their appearance:  spirals,
like the Milky Way, are shaped like
pinwheels irregulars
have no discernible shape at all;
and  ellipticals
are round- or oval-shaped
objects.
Spirals and irregulars are typically sites of ongoing star-formation and therefore contain young stars. Ellipticals, having finished their supply of fresh gas, cannot form stars any more and contain mostly very old stars. Spiral galaxies are a composite of stars and gas in a disk surrounding a central bulge, which is rather similar to an elliptical galaxy, just smaller. Waves in the disk form the spiral arms and cause the gas to collapse and form new stars. Therefore, the disk is rich in young stars. Older stars are typically found in the bulge. Elliptical galaxies and the bulges of spirals have been the subject of several decades of observational and theoretical work. For decades, astronomers thought that the rotation rate of these spherical star systems determined whether they would be round or oval shaped, with the more rapidly rotating ellipticals being the flattest. Detailed studies of thousands of ellipticals over the years now suggest an entirely different picture. Ellipticals and bulges are supported against their self-gravity, which would cause them to shrink, by the random velocities of the stars, pretty much like the motion of molecules in a hot gas. The distribution of stellar motion determines the final shape of the galaxy, that is whether it is spherical, oblate, or very flattened. In recent years, astronomers also have discovered that apparently simple galaxy shapes hide the complex, violent events that occurred in these galaxies long ago. Some contain dense cores in which millions of stars move in orbits completely different than stars farther out from the galaxy's centre. In many ways, the cores of some resemble isolated populations transplanted from outside the galaxy. Astronomers are beginning to believe that these cores are the remains of companion galaxies that were consumed when they wandered too close to these elliptical galaxies many millions of years ago. When galaxies collide, the rapidly changing gravitational fields also can synchronize the stellar orbits, creating great rings of stars which surround some ellipticals like haloes. Elliptical galaxies also contain some of the oldest stars in the universe. While spirals and irregulars continue to produce new stars even to the present day, most ellipticals stopped forming stars more than 10 billion years ago in what must have been one great star-forming epoch. Ellipticals contain little or no gas and dust of their own, apparently having consumed what they had when their stars were born long ago. Those ellipticals that contain higher concentrations of gas and dust apparently accumulated the material because they cannibalized their companion galaxies. The material accumulated from these cannibalizations collides as it sinks farther and farther into the galaxy's core, and in many instances, creates new generations of massive, luminous stars. Eventually over the course of millions of years, the gas reaches the centre of the galaxy where super massive black holes may lie in wait for a new supply of fuel. National Aeronautics and Space Administration NASA Headquarters Washington, D.C. December 1994 |
DOWNLOAD : UNIVERSE.Zip to create your own Universe! It is a neat little program!
Create realistic images of deep
space. First, create your star
field
and then add nebula, stars, vortex, lens
flares, planets, and
galaxies. Requires Windows 95, Windows
98, or Windows NT.
You can also register it at: http://www.diardsoftware.com
EXAMPLES:
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click to see enlarged picture (400x600)
