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Astronomy 330

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Meteorites are defined to be extraterrestrial fragments ... Others, as we have seen are much larger and produce impact craters or explode in the atmosphere. ... – PowerPoint PPT presentation

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Title: Astronomy 330


1
Astronomy 330
  • Lecture 24

http//solarsystem.nasa.gov/multimedia/display.cfm
?IM_ID848
2
Astronomy 330 Meteorites
  • Meteorites are defined to be extraterrestrial
    fragments which reach the surface of Earth.
  • Meteors while in the atmosphere, meteroids while
    in space
  • Meteorites reach the Earth frequently and their
    stones are recovered for study.
  • These fragments have a stony or a metallic
    composition and weigh a few kg.
  • Large falls of meteorites can also occur with 100
    to 1000 kg making it to Earth (most often these
    are broken up into many smaller pieces.

3
Astronomy 330
  • Others, as we have seen are much larger and
    produce impact craters or explode in the
    atmosphere.
  • There are many different types of meteorites.
  • This suggests the parent bodies (asteroids) are
    also varied.
  • Types are divided into stony, iron, and
    stony-iron.
  • Stony-iron meteorites are rare.

4
Astronomy 330
  • Iron meteorites are nearly pure metallic
    nickel-iron and have a high density of 7 g/cm3.
  • They are easily recognizable as extraterrestrial
    since iron and other metals on Earth are
    oxidized.
  • Stony meteorites resemble Earths rocks and
    stony-metallic meteorites are a mixture of the
    two.

5
Astronomy 330
  • A 2nd, more useful categorization is also used
    primitive or differentiated and is based on
    chemical properties.
  • If the meteorites chemistry resembles the early
    solar system materials it is called primitive.
  • Primitive meteorites have been altered little
    since the formation of the solar system.
  • All primitive meteorites are stony.
  • Meteorites which have experienced chemical change
    since their formation are called differentiated.

6
Astronomy 330
  • Differentiated meteorites solidified out of a
    molten state and appear to be pieces of larger,
    differentiated bodies that lost their volatiles
    and experienced much heating.
  • All iron, stony-iron and many of the stony
    meteorites are differentiated.
  • Some meteorites have uniform compositions, others
    seem to have been broken and mixed by impact
    processesthese are brecciasremember what
    breccias are?

7
Astronomy 330 Origins of Meteorites
  • Sky monitoring (continuous observation of the sky
    in a systematic way) has only seen 3 meteorites
    as they entered and traveled through the Earths
    atmosphere.
  • Doing this has allowed reconstruction of their
    orbits around the sun and shown them to have come
    from the asteroid belt.

8
Astronomy 330 Ages
  • Using radioactive isotope dating, all primitive
    meteorites have solidification ages of 4.5 - 4.6
    billion yearsthe age of the solar system.

9
Astronomy 330 Primitive Meteorites
  • Have chemical compositions that have remained
    unchanged and are similar to the Suns (except
    that they have no H, He, Ar, C, and O).
  • These meteorites are used to define solar
    abundances of rare elements which cannot be
    directly detected by observing the Sun.
  • Another name for primitive meteorites is
    chondritesthey contain chodrules.

10
Astronomy 330
  • Chondrules are about 1 mm in diameter and appear
    to be frozen droplets.
  • Not all Chondrites contain chondrules.
  • Appear as light gray rocks.
  • Many are breccias and their density is about 3
    g/cm3, similar to Earths rocks.
  • Many show evidence of having been heated in the
    past or the effects of liquid waterthese are
    partially modified meteorites and not completely
    primitive.

11
Astronomy 330
  • Many primitive meteorites contain grains of
    metallic iron which makes up about 10-30 of the
    total weight.
  • Primitive meteorites are therefore further
    classed by their metal content.
  • H (high iron), L (Low iron) and LL (very low
    iron).
  • Also contain silicon, oxygen, magnesium and
    sulfur.
  • Since all the primitive meteorites have the same
    age they all formed together in the solar system.

12
Astronomy 330 Carbonaceous meteorites
  • The most primitive of the primitive meteorites.
  • Rich in C (a few percent by weight) and also
    volatile compounds such as water.
  • Almost no metallic iron.
  • Dark gray to black in color.
  • Less dense, 2.5 g/cm3.
  • Probably formed in the cooler regions of solar
    nebula to have retained volatiles.

13
Astronomy 330
  • Carbonaceous meteorites also contain complex
    organic compounds (up to 3 of their
    composition).
  • This was the first evidence that complex carbon
    chemistry can occur outside the Earth and not be
    associated with life.
  • Also, this indicates that meteorites may have
    played a role supplying the early Earth with the
    primitive carbon compounds from which life arose.

14
Astronomy 330
  • Some of these meteorites also have been shown to
    have amino acidsthe Murchison meteorite.
  • These meteorites contain left-handed and
    right-handed forms of these organic molecules.
    Life on Earth uses exclusively the left-handed
    form. This indicates the meteorites have not
    been contaminated.
  • Also the C12/C13 ratio is different in the
    meteorites when compared to that on the Earth.

15
Astronomy 330 Differentiated Meteorites
  • Composed of materials that have been melted AFTER
    they condensed from the solar nebula.
  • Their parent bodies underwent some process of
    heating differentiated.
  • Also called achondrites.
  • Iron meteorites are the best example of this type
    and consistent of almost pure metallic
    nickel-iron (trace quantities of sulfur, carbon,
    and other metals such as platinum are also
    detected).

16
Astronomy 330
  • Nickel makes up about 10 by weight of such
    meteorites.
  • Iron meteorites make up of 2 of all meteorites
    falling to Earth.
  • Such meteorites are fragments of the metallic
    cores of their parent bodies.
  • These parent bodies must have been on the order
    of the size of todays planets to have contained
    metallic cores.
  • Chemical analysis indicates that there must have
    been at least 12 different sources for these iron
    meteorites.

17
Astronomy 330
  • The stony-metal meteorites are thought to have
    originated from the location where the parent
    body transitions from its metallic core to a
    silicate mantle.
  • The pure iron meteorites cannot be dated. The
    stony-irons can and again are 4.5-4.6 billion
    years old. Hence, their fully differentiated
    parent bodies must have been around at this time.

18
Astronomy 330
  • These is a group of differentiated stony
    meteorites as well which seem to have come from
    the crusts of these differentiated parent bodies.
  • They are composed of basalts, crystallized lavas
    (like on Earth or the Moon).
  • Also, they are breccias so they must have been
    present on the surfaces of these parent bodies
    for a long time.
  • Several of these type of meteorites are thought
    to have come from specific objectsVesta and Mars.

19
Astronomy 330 Source of Primitive Meteorites
  • Must have been small (less than a few hundred km)
    and condensed directly out of the solar nebula.
  • Large bodies would have retained too much heat
    and altered the meteorites from their primitive
    state.
  • Must have included organic compounds and liquid
    water.
  • Further, the variety of the chemical composition
    of the primitive meteorites indicates that their
    must have been many different parent bodies.

20
Astronomy 330 Source of Differentiated Meteorites
  • Parent bodies must have been no larger than 100
    km in diameterroughly the same size as the
    undifferentiated parent bodies.
  • Why did one set of bodies differentiate and the
    other did not? We dont know!

21
Astronomy 330 Reading
  • Read Chapter 4 of Morrison and Owen
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