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_Meteoroids and Meteorites_

_Copyright © 1995-1999 by Rosanna L. Hamilton. All rights reserved._

_Meteoroids & Meteorites_
Introduction
[11]Pictures of Meteorites
[12]References

_Meteorite Science_
[13]Terrestrial Impact Craters
[14]Life from Mars: The Discovery
[15]Meteorite Image Index

_Educator's Guides_
[16]Meteoroids & Space Debris
[17]Impact Craters
[18]Micrometeorites

_Other Resources_
[19]Asteroid/Comet Impact Hazards

[20][LINK] 

The term meteor comes from the Greek _meteoron_, meaning phenomenon in
the sky. It is used to describe the streak of light produced as matter
in the solar system falls into Earth's atmosphere creating temporary
incandescence resulting from atmospheric friction. This typically
occurs at heights of 80 to 110 kilometers (50 to 68 miles) above
Earth's surface. The term is also used loosely with the word meteroid
referring to the particle itself without relation to the phenomena it
produces when entering the Earth's atmosphere. A meteoroid is matter
revolving around the sun or any object in interplanetary space that is
too small to be called an asteroid or a comet. Even smaller particles
are called micrometeoroids or cosmic dust grains, which includes any
interstellar material that should happen to enter our solar system. A
meteorite is a meteoroid that reaches the surface of the Earth without
being completely vaporized.

One of the primary goals of studying meteorites is to determine the
history and origin of their parent bodies. Several achondrites sampled
from Antarctica since 1981 have conclusively been shown to have
originated from the moon based on compositional matches of lunar rocks
obtained by the Apollo missions of 1969-1972. Sources of other
specific metorites remain unproven, although another set of eight
achondrites are suspected to have come from Mars. These meteorites
contain atmospheric gases trapped in shock melted minerals which match
the composition of the Martian atmosphere as measured by the
[21]Viking landers in 1976. All other groups are presumed to have
originated on asteroids or comets; the majority of meteorites are
believed to be fragments of asteroids.

Meteorite Types & Percentage that Falls to the Earth
* Stony meteorites
+ Chondrites (85.7%)
o Carbonaceous
o Enstatite
+ Achondrites (7.1%)
o HED group
o SNC group
o Aubrites
o Ureilites

* Stony iron meteorites (1.5%)
+ Pallasites
+ Mesosiderites
* Iron meteorites (5.7%)

Meteorites have proven difficult to classify, but the three broadest
groupings are stony, stony iron, and iron. The most common meteorites
are chondrites, which are stony meteorites. Radiometric dating of
chondrites has placed them at the age of 4.55 billion years, which is
the approximate age of the solar system. They are considered pristine
samples of early solar system matter, although in many cases their
properties have been modified by thermal metamorphism or icy
alteration. Some meteoriticists have suggested that the different
properties found in various chondrites suggest the location in which
they were formed. Enstatite chondrites contain the most refractory
elements and are believed to have formed in the inner solar system.
Ordinary chondrites, being the most common type containing both
volatile and oxidized elements, are thought to have formed in the
inner asteroid belt. Carbonaceous chondrites, which have the highest
proportions of volatile elements and are the most oxidized, are
thought to have originated in even greater solar distances. Each of
these classes can be further subdivided into smaller groups with
distinct properties.

Other meteorite types which have been geologically processed are
achondrites, irons and pallasites. Achondrites are also stony
meteorites, but they are considered differentiated or reprocessed
matter. They are formed by melting and recrystallization on or within
meteorite parent bodies; as a result, achondrites have distinct
textures and mineralogies indicative of igneous processes. Pallasites
are stony iron meteorites composed of olivine enclosed in metal. Iron
meteorites are classified into thirteen major groups and consist
primarily of iron-nickel alloys with minor amounts of carbon, sulfur,
and phosphorus. These meteorites formed when molten metal segregated
from less dense silicate material and cooled, showing another type of
melting behavior within meteorite parent bodies. Thus,
meteoritescontain evidence of changes that occurred on the parent
bodies from which they were removed or broken off, presumably by
impacts, to be placed in the first of many revolutions.

The motion of meteoroids can be severely perturbed by the
gravitational fields of major planets. Jupiter's gravitational
influence is capable of reshaping an asteroid's orbit from the main
belt so that it dives into the inner solar system and crosses the
orbit of Earth. This is apparently the case of the Apollo and Vesta
asteroid fragments.

Particles found in highly correlated orbits are called a stream
components and those found in random orbits are called sporadic
components. It is thought that most meteor streams are formed by the
decay of a comet nucleus and consequently are spread around the
original orbit of the comet. When Earth's orbit intersects a meteor
stream, the meteor rate is increased and a meteor shower results. A
meteor shower typically will be active for several days. A
particularly intense meteor shower is called a meteor storm. Sporadic
meteors are believed to have had a gradual loss of orbital coherence
with a meteor shower due to collisions and radiative effects, further
enhanced by gravitational influences. There is still some debate
concerning sporadic meteors and their relationship with showers.

Pictures of Meteorites

_Chondrite Meteorite_
This meteorite was collected from the Allan Hills in Antarctica.
Meteorites are bits of rock that are captured by a planet's gravity
and pulled to the surface. This meteorite is of a type named chondrite
and is thought to have formed at the same time as the planets in the
solar nebula, about 4.55 billion years ago. _(Courtesy NASA/JPL)_
_Achondrite Meteorite_
Discovered at Reckling Peak, Antarctica, this type of meteorite is
known as an achondrite. It has a [22]basaltic composition and was
probably formed when an asteroid melted about 4.5 billion years ago.
The asteroid broke up some time later and this small piece of the
asteroid was captured by Earth's gravity and fell to the ground.
_(Courtesy NASA/JPL)_
_Iron Meteorite_
This iron meteorite was found at Derrick Peak, Antarctica. This type
of meteorite gets its name because it is mostly made of the elements
iron and nickel. This sample is probably a small piece from the core
of a large asteroid that broke apart. _(Courtesy NASA/JPL)_
_Martian Meteorite_
Even though this meteorite was collected in Elephant Moraine,
Antarctica in 1979, some scientists believe that it came from the
planet Mars. The minerals found in this rock are similar to those that
scientists expect to find in rocks on Mars. This meteorite also
contains vesicles, or shiny pockets, which contain air very much like
the air measured on Mars by the Viking spacecraft. This meteorite is
180 million years old. _(Courtesy NASA/JPL)_
_A Martian Meteorite_
This meteorite, called EETA 79001, was found on the ice in Antarctica,
and is quite likely from Mars. For scale, the cube at the lower right
is 1 centimeter on a side. The meteorite is partly covered by a black
glassy layer, the fusion crust. The fusion crust forms when the
meteorite enters the Earth's atmosphere at high speed. Friction
heating melts the outer portion of the meteorite. Inside, the
meteorite is gray. It is a [23]basalt, very similar to basalts found
on Earth. It formed in a volcanic eruption about 180 million years
ago. This meteorite is quite likely from Mars because it contains a
small amount of gas that is chemically identical to the Martian
atmosphere. _(Courtesy LPI)_
_Microscopic View of a Martian Meteorite_
Rocks are often made of small mineral grains that can't be seen
clearly without a microscope. To see these small grains, scientists
grind and polish rock samples very thin (0.03 millimeters) so light
can pass through them. This microscopic view, 2.3 millimeters (.09
inches) across, is in false color, produced by holding polarizing
filters above and below the microscopic slide. These filters cause
different minerals to have distinctive colors, allowing easy
identification of the minerals. Most of this meteorite (in yellow,
green, pink, and black) is the mineral olivine, which is common in
some basaltic rocks. The striped grain near the center is the mineral
pyroxene. _(Courtesy Allan Treiman, LPI)_
_Vesta Meteorite_
This meteorite is assumed to be a sample of the crust of the asteroid
[24]Vesta, which is only the third solar system object beyond Earth
where scientists have a laboratory sample (the other extraterrestrial
samples are from Mars and the Moon). The meteorite is unique because
it is made almost entirely of the mineral pyroxene, common in lava
flows. The meteorite's mineral grain structure also indicates it was
once molten, and its oxygen isotopes are unlike oxygen isotopes found
for all other rocks of the Earth and Moon. The meteorite's chemical
identity points to the asteroid Vesta because it has the same unique
spectral signature of the mineral pyroxene.

Most of the identified meteorites from Vesta are in the care of the
Western Australian Museum. This 1.4 pound (631 gm) specimen comes from
the New England Meteoritical Services. It is a complete specimen
measuring 9.6 x 8.1 x 8.7 centimeters (3.7 x 3.1 x 3.4 inches),
showing the fusion crust, evidence of the last stage in its journey to
Earth. _(Photo Credit: R. Kempton, New England Meteoritical Services)_

References

Beatty, J. K. and A. Chaikin. _The New Solar System_. Massachusetts:
Sky Publishing, 3rd Edition, 1990.

Maran, Stephen P. _The Astronomy and Astrophysics Encyclopedia_. New
York: Van Nostrand Reinhold, pp. 430-445, 1992.

Seeds, Michael A. _Horizons_. Belmont, California: Wadsworth, 1995.

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Hamilton. All rights reserved._ [29]Privacy Statement.

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