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_Comet Introduction_

_Table of Contents_
Comet Introduction
[11]Comet Animation
[12]Views of Comets

_Comets_
[13]Comet Borrelly
[14]Halley's Comet
Shoemaker-Levy 9
[15]Shoemaker-Levy 9 Background
[16]Shoemaker-Levy 9 Impact
[17]Hubble PR - Collision Results
[18]Comet LINEAR
[19]Hale-Bopp Fails Emission Tests
[20]but Reveals Comet Origin
[21]Comet Image/Animation Gallery

_Comet Discoveries_
[22]Kuiper Belt Objects
[23]Comets Beyond Neptune
[24]Comet Tutorial
[25]Make a Comet Nucleus
[26]Comet Space Exploration Chronology

[27][LINK] 

Comets are small, fragile, irregularly shaped bodies composed of a
mixture of non-volatile grains and frozen gases. They have highly
elliptical orbits that bring them very close to the Sun and swing them
deeply into space, often beyond the orbit of Pluto.

Comet structures are diverse and very dynamic, but they all develop a
surrounding cloud of diffuse material, called a coma, that usually
grows in size and brightness as the comet approaches the Sun. Usually
a small, bright nucleus (less than 10 km in diameter) is visible in
the middle of the coma. The coma and the nucleus together constitute
the head of the comet.

As comets approach the Sun they develop enormous tails of luminous
material that extend for millions of kilometers from the head, away
from the Sun. When far from the Sun, the nucleus is very cold and its
material is frozen solid within the nucleus. In this state comets are
sometimes referred to as a "dirty iceberg" or "dirty snowball," since
over half of their material is ice. When a comet approaches within a
few [28]AU of the Sun, the surface of the nucleus begins to warm, and
volatiles evaporate. The evaporated molecules boil off and carry small
solid particles with them, forming the comet's coma of gas and dust.

When the nucleus is frozen, it can be seen only by reflected sunlight.
However, when a coma develops, dust reflects still more sunlight, and
gas in the coma absorbs ultraviolet radiation and begins to fluoresce.
At about 5 AU from the Sun, fluorescence usually becomes more intense
than reflected light.

As the comet absorbs ultraviolet light, chemical processes release
hydrogen, which escapes the comet's gravity, and forms a hydrogen
envelope. This envelope cannot be seen from Earth because its light is
absorbed by our atmosphere, but it has been detected by spacecraft.

The Sun's radiation pressure and solar wind accelerate materials away
from the comet's head at differing velocities according to the size
and mass of the materials. Thus, relatively massive dust tails are
accelerated slowly and tend to be curved. The ion tail is much less
massive, and is accelerated so greatly that it appears as a nearly
straight line extending away from the comet opposite the Sun. The
following view of Comet West shows two distinct tails. The thin blue
[29]plasma tail is made up of gases and the broad white tail is made
up of microscopic dust particles.

[30][LINK] 
_Comet West_

Each time a comet visits the Sun, it loses some of its volatiles.
Eventually, it becomes just another rocky mass in the solar system.
For this reason, comets are said to be short-lived, on a cosmological
time scale. Many scientists believe that some [31]asteroids are
extinct comet nuclei, comets that have lost all of their volatiles.

Comet Animation

* [32]Historical background of comets.

Views of Comets

_Comet Kohoutek_
This color photograph of the comet Kohoutek was taken by members of
the lunar and planetary laboratory photographic team from the
University of Arizona. They photographed the comet from the Catalina
observatory with a 35mm camera on January 11, 1974. _(Courtesy NASA)_
Comet Hyakutake
These Hubble Space Telescope images of comet Hyakutake were taken on
March 25, 1996 when the comet passed at a distance of 9.3 million
miles from [33]Earth. These images focus on a very small region near
the heart of the comet, the icy, solid nucleus and provide an
exceptionally clear view of the near-nucleus region of the comet.

The left image is 2070 miles across (3340 km) and shows that most of
the dust is being produced on the sunward-facing hemisphere of the
comet. Also at upper left are three small pieces which have broken off
the comet and are forming their own tails. Icy regions on the nucleus
are activated as they rotate into sunlight, ejecting large amounts of
dust in the jets that are faintly visible in this image. Sunlight
striking this dust eventually turns it around and "blows" it into the
tailward hemisphere.

The bottom-right image is an expanded view of the near-nucleus region
and is only 470 miles (760 km) across. The nucleus is near the center
of the frame, but the brightest area is probably the tip of the
strongest dust jet rather than the nucleus itself. Presumably, the
nucleus surface lies just below this bright jet. The top-right image
shows pieces of the nucleus that apparently broke off. The image shows
at least three separate objects that are probably made up of
coarse-grained dust. Large fragments of the nucleus would not be
accelerated into the tail, which appears to be the case in this image.
_(Credit: H. A. Weaver--Applied Research Corp., HST Comet Hyakutake
Observing Team, and NASA)_
_First X-Rays From Comet Hyakutake Discovered_
This image shows the discovery of a strong X-ray radiation signal
coming from comet Hyakutake. The image was made on March 27, 1996
using Germany's orbiting ROSAT satellite. The comet was near its
closest approach to the Earth at a distance of less than 10 million
miles when X-ray emmisions were first detected by ROSAT. The strength
and rapid changes in intensity of the comet's X-ray emission both
surprised and puzzled astronomers. "We had no clear expectation that
comets shine in X-rays," said Dr. Michael J. Mumma of NASA's Goddard
Space Flight Center, Greenbelt, MD. X-rays have never been found from
a comet before, and scientists had optimistically predicted an
intensity that turned out to be about 100 times weaker than the
radiation actually detected by ROSAT. Strong changes in the brightness
of the X-rays were another surprise. There were pronounced increases
and decreases in the X-ray brightness from one ROSAT observation to
another, typically over a time difference of a few hours.

Still another puzzle is the nature of the physical process that
generates the X-rays, but the ROSAT image may contain clues to this
process. In the image, the X-rays from the comet seem to come from a
crescent-shaped region on the sunward side of Comet Hyakutake. One
preliminary theory is that X-ray emission from the Sun was absorbed by
a cloud of gaseous water molecules surrounding the nucleus of the
comet, and then were re-emitted by the molecules in a process
physicists call "fluorescence." According to this idea, the cloud is
so thick that its sunward side absorbs nearly all the incoming solar
X-rays, so that none reach the remainder of the cloud. This could
explain why the cometary X-ray emission has the form of a crescent,
rather than that of a sphere around the nucleus. A second possible
explanation is that the X-rays are produced from the violent collision
between the comet material and the supersonic "wind" of plasma and
particles streaming away from the Sun.
_Comet 1993a Mueller_
This is a CCD image of comet 1993a Mueller, taken on October 6, 1993
with a 288mm f/5.2 Schmidt-Cassegrain telescope. The comet has a coma
diameter of 3' and a fan-shaped tail, up to 7' long. _(Courtesy Erich
Meyer and Herbert Raab, Austria)_
_Comet West (1975)_
This photograph was taken by amateur astronomer John Loborde on March
9, 1976. This picture shows two distinct tails. The thin blue
[34]plasma tail is made up of gases and the broad white tail is made
up of microscopic dust particles. _(Courtesy [35]John Laborde)_
_Comet West (1975)_
This image of comet West was taken by John Laborde at the Tierra Del
Sol Observatory site in San Diego County. The exposure was 30 minutes
with a 135 mm Nikon lens. _(Courtesy [36]John Laborde)_
_Comet Hale-Bopp_
These NASA Hubble Space Telescope pictures of comet Hale-Bopp show a
remarkable "pinwheel" pattern and a blob of free-flying debris near
the nucleus. The bright clump of light along the spiral (above the
nucleus, which is near the center of the frame) may be a piece of the
comet's icy crust that was ejected into space by a combination of ice
evaporation and the comet's rotation, and which then disintegrated
into a bright cloud of particles.

Although the "blob" is about 3.5 times fainter than the brightest
portion at the nucleus, the lump appears brighter because it covers a
larger area. The debris follows a spiral pattern outward because the
solid nucleus is rotating like a lawn sprinkler, completing a single
rotation about once per week.
_Comet Hale-Bopp_
This image of comet Hale-Bopp was taken by John Laborde with his home
designed and built, 8.8" f/3.7 Wright Schmidt Camera. The picture was
taken at the Tierra Del Sol Observatory site in San Diego County with
a 25 minute exposure on Kodak PPF400 film. _(Courtesy [37]John
Laborde)_
_Comet Ikeya-Seki_
This image of comet Ikeya-Seki was taken by John Laborde in Poway,
California just before dawn. The exposure was 15 minutes with a 55 mm
Nikon lens. _(Courtesy [38]John Laborde)_

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References

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13. http://www.solarviews.com/eng/borrelly.htm
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24. http://www.solarviews.com/eng/comet/toc.htm
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31. http://www.solarviews.com/eng/asteroid.htm
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35. mailto:jlaborde at ix.netcom.com
36. mailto:jlaborde at ix.netcom.com
37. mailto:jlaborde at ix.netcom.com
38. mailto:jlaborde at ix.netcom.com
39. http://www.solarviews.com/eng/homepage.htm
40. http://www.solarviews.com/eng/asteroid.htm
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