Solar System Fluff

Full window version (looks a little nicer). Click <Back> button to get back to small framed version with content indexes.

This chapter covers all of the solar system that is not the planets or the Sun: meteorites, asteroids, and comets. I group them all together as ``solar system fluff'' because the objects are much smaller than planets and most moons. The ``fluff'' may be small in size but certainly not in importance. We get clues of the origin of the solar system from these small objects.

Asteroids

Though there are over a million asteroids, the volume of space they inhabit is very large, so they are far apart from one another. Unlike the movie The Empire Strikes Back, where the spacecrafts flying through an asteroid belt could not avoid crashing into them, real asteroids are at least tens of thousands of kilometers apart from each other. Several spacecraft sent to the outer planets have travelled through the asteroid belt with no problems.

Two of the three types of asteroids are represented by the asteroids that have been explored up close with spacecraft. Mathilde (left) is a dark C-type (brightness enhanced several times to match the other two). Gaspra and Ida are S-type asteroids.

There are three basic types of asteroids:

1. C: they are carbonaceous---made of silicate materials with a lot of carbon compounds so they appear very dark. They reflect only 3 to 4% of the sunlight hitting them. You can tell what they are made of by analyzing the spectra of sunlight reflecting off of them. This reflectance spectra shows that they are primitive, unchanged since they first solidified about 4.6 billion years ago. A sizable fraction of the asteroids are of this type. The asteroid called Mathilde, recently explored by the NEAR spacecraft is an example of this type (see picture above).
2. S: they are made of silicate materials without the dark carbon compounds so they appear brighter than the C types. They reflect about 15 to 20% of the sunlight hitting them. Most of them appear to be primitive and they make up a smaller fraction of the asteroids than the C types. Gaspra and Ida, explored by the Galileo spacecraft on its way to Jupiter, are examples of this type (see picture above).
3. M: they are made of metals like iron and nickel. These rare type of asteroids are brighter than the S and C types. We think they are the remains of the cores of differentiated objects. Large objects were hot enough in the early solar system so that they were liquid. This allowed the dense materials like iron and nickel to sink to the center while the lighter material like ordinary silicate rock floated up to the top. Smaller objects cooled off quicker than larger objects, so they underwent less differentiation. In the early solar system, collisions were much more common and some of the smaller differentiated large asteroids collided with one another, breaking them apart and exposing their metallic cores.

Meteorites

If the little piece of rock makes it to the surface without burning up, it is called a meteorite. There are three basic types of meteorites.

1. Stones: they are made of silicate material with a density around 3 (relative to the density of water) and look like ordinary Earth rocks. This makes them hard to distinguish from Earth rocks so they don't stand out. About 95 to 97% of the meteorites are of these type. About 85% of the stones are primitive, unchanged since they first solidified about 4.6 billion years ago. Most of the primitive stones have chondrules---round glassy structures 0.5 to 5 millimeters across embedded in the meteorites. They are solified droplets of matter from the early solar nebula and are the oldest part of a primitive meteorite.
   
   A carbonaceous meteorite containing chondrules (courtesy of the Planetary Data Center).

   The oldest of the stone meteorites are the carbonaceous meteorites. They contain silicates, carbon compounds (giving them their dark color), and a surprisingly large amount of water (about 22%). They are probably chips of C-type asteroids. Some of the carbonaceous meteorites have organic molecules called amino acids. Amino acids can be connected together to form proteins that are used in the biological processes of life. There is the possibility that meteorites like these may have been the seeds of life on the Earth. In addition, these type of meteorites may have provided the inner planets with a lot of water. The terrestrial planets may have been so hot when they formed that most of the water in them at formation evaporated away to space. The impact of millions to billions of carbonaceous meteorites in the early solar system may have replenished the water supply on the terrestrial planets.

   About 10 to 12% of the stones are from the crust of differentiated parent objects. Therefore, they are younger (only 4.4 billion years old). The lighter-colored stones are chips from the S-type of asteroids.

2. Stoney-Irons: only 1% of the meteorites are of this type. They have a variable mixture of metal (iron and nickel) and rock (silicates) and have densities ranging from 4 to 6 (relative to the density of water). They come from a differentiated object at the boundary between the metal core and the rock crust. They are 4.4 billion years old.
3. Irons: although they make up about 40% of the meteorites found worldwide, only 2 to 3% of the meteorites are these type. They make up so many of the ones found because they are easily distinguished from Earth rocks. They are noticeably denser than Earth rocks, they have a density around 7. They come from the core of a differentiated body and are made of iron and nickel. They are 4.4 billion years old. Irons sometimes have large, coarse-grained crystalline patterns (``Widmanstatten patterns'') that is evidence that they cooled slowly.
   
   An iron meteorite (courtesy of the Planetary Data Center).

Finding Meteorites

To get an accurate number for the proportion of meteorites that fall to the Earth (an unbiased sample), meteorite searchers go to a place where all types of rocks will stand out. The best place to go is Antarctica where the stable, white ice pack makes darker meteorites easy to find. Meteorites that fell thousands of years ago can still be found in Antarctica without significant weathering. Since the 1980's thousands of meteorites have come from here. For further exploration, check out the Antarctica Meteorite web site at the Planetary Materials Curation office of NASA and the ANSMET site at Case Western Reserve University.

Meteorites stand out against the snow and ice background of Antarctica.

Most meteorites are pieces of asteroids, but a few are from the Moon. A select few, the Shergotty-Nakhla-Chassigny (SNC) meteorites, may be from Mars. The relative abundances of magnesium and heavy nitrogen (N-15) gases trapped inside the SNC meteorites is similar to the martian atmosphere as measured by the Viking landers and unlike any meteorites from the asteroids or Moon. Also, the isotope ratios of argon and xenon gas trapped in the meteorites most closely resemble the martian atmosphere and are different than the typical meteorite. The analysis of the soil and rocks by the Mars Pathfinder confirm this.

A meteorite blasted from Mars.

Most SNC meteorites are about 1.4 Gyr old, but the one with suggestions of extinct Martian life is about 4.5 Gyr old. The discovery was published in the August 16, 1996 issue of the journal Science. Non-subscribers can find a copy of the article here. Recent studies of the meteorite have cast considerable doubt on the initial claims for fossil microbes in the rock. There is strong evidence of contamination by organic molecules from Earth, so this meteorite does not provide the conclusive proof hoped for. A detailed description of SNC meteorites is given at http://www.jpl.nasa.gov/snc/.

Radioactive Dating

To measure the passage of long periods of time, scientists take advantage of a regularity in certain unstable atoms. In radioactive atoms the nucleus will spontaneously change into another type of nucleus. When looking at a large number of atoms, you see that a certain fraction of them will change or decay in a certain amount of time that depends on the type of atom---more specifically, the type of nucleus. Radioactive dating is an absolute dating system because you can determine accurate ages from the number of remaining radioactive atoms in a rock sample. Most of the radioactive isotopes used for radioactive dating of rock samples have too many neutrons in the nucleus to be stable.

An isotope is a particular form of an element. All atoms of an element have the same number of protons in their nucleus and behave the same way in chemical reactions. The atoms of an isotope of a given element have same number of protons AND neutrons in their nucleus. Different isotopes of a given element will have the same chemistry but behave differently in nuclear reactions. In a radioactive decay, the original radioactive isotope is called a parent isotope and the resulting isotope after the decay is called a daughter isotope. For example, Uranium-238 is the parent isotope that breaks apart to form the daughter isotope Lead-204.

Radioactive Dating Method

Radioactive isotopes will decay in a regular exponential way such that one-half of a given amount of parent material will decay to form daughter material in a time period called a half-life. A half-life is NOT one-half the age of the rock! When the material is liquid or gaseous, the parent and daughter isotopes can escape, but when the material solifies, they cannot so the ratio of parent to daughter isotopes is frozen in. The parent isotope can only decay, increasing the amount of daughter isotopes. Radioactive dating gives the solidification age.

There are two simple steps for radioactive dating:

1. Find out how many times you need to multiply (1/2) by itself to get the observed fraction of remaining parent material. Let the number of the times be n. For example 1/8 = (1/2) × (1/2) × (1/2), so n = 3. The number n is the number of half-lives the sample has been decaying. If some material has been decaying long enough so that only 1/4 of the radioactive material is left, the sample is 2 half-lives old: 1/4 = (1/2) × (1/2), n =2.
2. The age of the sample in years = n × (one half-life in years).

How do you do that? If 1/8 of the original amount of parent isotope is left in a radioactive sample, how old is the sample? Answer: After 1 half-life, there is 1/2 of the original amount of the parent left. After another half-life, there is 1/2 of that 1/2 left = 1/2 × 1/2 = 1/4 of original amount of the parent left. After yet another half-life, there is 1/2 of that 1/4 left = 1/2 × 1/2 × 1/2 = 1/8 of the original amount of the parent left (which is the fraction asked for). So the rock is 1 half-life + 1 half-life + 1 half-life = 3 half-lives old (to get the age in years, simply multiply 3 by the half-life in years).

If you have a fraction that is not a multiple of 1/2, then it is more complicated. The age = [ln(original amount of parent material / current amount of parent material) / ln(2)] × (half-life in years), where ln() is the ``natural logarithm'' (it is the ``ln'' key on a scientific calculator).

If Amount of Original Is Not Known

One common sense rule to remember is that the number of parent isotope atoms + the number of daughter isotope atoms = an unchanging number throughout time. The number of parent isotopes decreases while the number of daughter isotopes increases but the total of the two added together is a constant. You need to find how much of the daughter isotopes in the rock (call that isotope ``A'' for below) are not the result of a radioactive decay of parent atoms. You then subtract this amount from the total amount of daughter atoms in the rock to get the number of decays that have occurred since the rock solified. Here are the steps:

1. Find another isotope of the same element as the daughter that is never a result of radioactive decay (call that isotope ``B'' for below). Isotopes of a given element have the same chemical properties, so a radioactive rock will incorporate the NONradioactively derived proportions of the two isotopes in the same proportion as any nonradioactive rock.
2. Measure the ratio of isotopes A and B in a nonradioactive rock. This ratio, R, will be the primitive (initial) proportion of the two isotopes.
3. Multiply the amount of the non-daughter isotope (isotope B) in the radioactive rock by the ratio of the previous step: (isotope B) × R = initial amount of daughter isotope A that was not the result of decay.
4. Subtract the initial amount of daughter isotope A from the rock sample to get the amount of daughter isotope A that IS due to radioactive decay. That number is also the amount of parent that has decayed (remember the rule #parent + #daughter = constant). Now you can determine the age as you did before.

Is Radioactive Dating Valid?

1. The rate of decay should follow a simple exponential decline based on the simple theory of probability in statistics. This same probability theory is used to figure the odds of winning by gamblers.
2. An exponential decay is seen for short-lived isotopes with half-lives of only a few days.
3. For the decades they have been observed, the long-lived isotopes also follow an exponential decay.
4. The decay probability should not depend on time because:
   • An exponential decay IS observed for short-lived isotopes.
   • Decays are nuclear reactions. Nuclear reactions only care about size scales of 10^-13 centimeters (100 million times smaller than the wavelength of visible light). The composition and state of the surrounding material will not affect the rate of decay.
   • The laws of nature or physics at the nuclear level should not change with time.
   • Astronomical observations show that the laws of physics are the same everywhere in the universe and have been unchanged for the past 15 billion years.

Effects of an Asteroid Impact on Earth

Known impact sites on the Earth's continents.

What follows is a condensation of an excellent article by Sydney van den Bergh called ``Life and Death in the Inner Solar System'' in the May 1989 issue of the Publications of the Astronomical Society of the Pacific (vol. 101, pages 500-509). He considers a typical impact scenario of a 10-kilometer object with density = 2.5 times that of water, impacting at a speed of 20 kilometers/second. Its mass = 1.31 trillion tons (1.31 × 10¹⁵ kilograms). A 1-kilometer object has a mass = 1.31 billion tons.

Explosion

On its way to the impact, the asteroid pushes aside the air in front of it creating a hole in the atmosphere. The atmosphere above the impact site is removed for several tens of seconds. Before the surrounding air can rush back in to fill the gap, material from the impact: vaporized asteroid, crustal material, and ocean water (if it lands in the ocean), escapes through the hole and follows a ballistic flight back down. Within two minutes after impact, about 10⁵ cubic kilometers of ejecta (10¹³ tons) is lofted to about 100 kilometers. If the asteroid hits the ocean, the surrounding water returning over the the hot crater floor is vaporized, sending more water vapor into the air.

There will be a crater regardless of where it lands. The diameter of the crater in kilometers is = (energy of impact)^(1/3.4)/10^6.77. Plugging in the typical impact values, you get a 150-kilometer diameter crater for the 10-kilometer asteroid and a 20-kilometer diameter crater for the 1-kilometer asteroid.

Meteor (Barringer) Crater in northern Arizona (about 1 kilometer across).

Chicxulub Crater in Yucatan, Mexico (from the one that may have killed off the dinosaurs).

Tsunami

Some values for the height of the tsunami at different distances from the impact site are given in the following table. The heights are given for the two typical asteroids, a 10-kilometer and a 1-kilometer asteroid.

Global Firestorm

Acid Rain

1. N₂ + O₂ ‚> NO (molecular nitrogen combined with molecular oxygen produces nitrogen monoxide)
   
2. 2NO + O₂ ‚> 2NO₂ (two nitrogen monoxide molecules combined with one oxygen molecule produces two nitrogen dioxide molecules)
   
3. NO₂ is converted to nitric and nitrous acids when it is mixed with water.

• destruction or damage of foliage;
• great amounts of weathering of continental rocks;
• the upper ocean organisms are killed. These organisms are responsible for locking up carbon dioxide in their shells (calcium carbonate) that would eventually become limestone. However, the shells will dissolve in the acid water. That along with the ``impact winter'' (described below) kills off about 90% of all marine nanoplankton species. A majority of the free oxygen from photosynthesis on the Earth is made by nanoplankton.
• The ozone layer is destroyed by O₃ reacting with NO. The amount of ultraviolet light hitting the surface increases, killing small organisms and plants (key parts of the food chain). The NO₂ causes respiratory damage in larger animals. Harmful elements like Beryllium, Mercury, Thallium, etc. are let loose.

Temperature Effects

The cooling is followed by a much more prolonged period of increased temperature due to a large increase in the greenhouse effect. The greenhouse effect is increased because of the increase of the carbon dioxide and water vapor in the air. The carbon dioxide level rises because the plants are burned and most of the plankton are wiped out. Also, water vapor in the air from the impact stays aloft for awhile. The temperatures are too warm for comfort for awhile.

Astronomers have requested funding for an observing program called Spaceguard to catalog all of the near-Earth asteroids and short period comets. Of the approximately 2000 asteroids that are thought to pose a threat of impacting Earth, less than 10% have been found so far. The international program would take 10 years to create a comprehensive catalog of all of the hazardous asteroids and comets. The cost for the entire program (building six special purpose telescopes and operation costs for ten years) would be less than what it costs to make a popular movie like Deep Impact or Armageddon. Select the hot links in this paragraph to find out more about Spaceguard. Another nice site is the Asteroid and Comet Hazards site at NASA.

Vocabulary

Review Questions

1. Where are most of the asteroids found?
2. Why are spacecraft able to pass through the asteroid belt without getting hit?
3. What are the three types of asteroids and what are they made of?
4. Why are more meteors seen after midnight?
5. What are the proportions of the three types of meteorites and what are they made of?
6. What type of asteroid does each type of meteorite correspond to?
7. Which meteorites are primitive and why are they particularly important for understanding the origin of the planets?
8. What makes carbonaceous meteorites so special?
9. Why are chondrules especially important for solar system formation models? What type of meteorite are they likely to be found in?
10. How old are the various types of meteorites and why are they used to find the age of the solar system?
11. Why do iron meteorites make up 40% of the ``finds'', but are only 2 to 3% of the total meteorites? What causes the biasing of the ``finds''?
12. Why is Antarctica a good place to get an unbiased sample of meteorites?
13. What makes SNC meteorites so unique and how are they different than other types of meteorites?
14. Why are iron and stoney-iron meteorites thought to come from a differentiated body?
15. Does radioactive dating give us relative or absolute ages for rocks? What type of ``age'' does it tell us?
16. How do you use the half-life to find the age of radioactive rocks?
17. If the half-life of a radioactive sample is 1 month, is a sample of it completely decayed after 2 months? If not, how much is left?
18. Uranium-235 has a half-life of 700 million years. How long will you have to wait until a 1-kilogram chunk decays so that only 0.0625 kilograms (1/16 kg) is left?
19. How are the very old ages derived for some radioactive rocks known to be correct?
20. If a large asteroid were to hit Earth, how much of the Earth's surface would be affected?

Go to Earth-Venus-Mars section

Comets and solar system formation sections

Go to Astronomy Notes beginning

Go to Astronomy 1 homepage

last update: 18 February 1999