| Geology 105 - Paleontology | ||||||
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1. Unaltered remains
This does not mean the organism is unchanged, but that the original material of the organism has not been changed to another substance. The fossil may have lost water, or color, or the proteins of the soft tissue may have degraded.
a. Unaltered hard and soft parts: mummification, freezing, encasement in amber (fossilized tree sap). Very very rare, usually only very young fossils.
b. Unaltered hard parts: teeth and very recent shells, bone or shell encased in petroleum or in petroleum-containing sediments.
2. Altered remains
a. Permineralization: pore spaces within the fossil are filled with mineral, usually silica. Petrified wood, bone.
b. Recrystallization: original mineral has recrystallized, either to different crystal system (aragonite to calcite) or by crystals growing. The original fine structure of the fossil is lost.
c. Replacement: original mineral has been dissolved away and replaced by a different mineral. Usually the original mineral was aragonite or calcite, and it has been replaced by silica (in oxidizing and acidic conditions) or pyrite (in reducing conditions, in the absence of oxygen). Under some conditions, replacement happens on an atom-by-atom basis, and the fine structure of the fossil is preserved in the new mineral. Recognizing replacement requires that you first be able to recognize what mineral you are looking at, and then that you know what the original skeletal material was. See "Skeletal Materials" below.
d. Carbonization: the soft parts of the organism were compressed and heated, driving off all the volatiles (H, N, O). A carbon film is left behind. Most common in plants, soft-bodied organisms, organisms with phosphate skeletons, organisms with chitin skeletons, and sometimes fish (under the right environmental conditions).
3. Impressions
Sometimes an organism will leave an imprint in sediment. If that imprint is either rapidly buried or left undisturbed during slow burial, it can be lithified and become a fossil. We call shallow imprints impressions (common for leaves and flat shells). Deeper imprints are called molds. If a mold later fills with sediment or minerals, it will form a copy of the original fossil called a cast.
4. Traces
Trace fossils are other kinds of evidence that an organism existed. Trace fossils include tracks, trails and footprints; burrows and other dwellings; tools; coprolites (fossilized excrement); and chemical fossils, which is chemical evidence of the existence of an organism. One of the most common but least useful kinds of trace fossils is bioturbation, evidence that organisms have churned through sediment. Bioturbation is recognized by the complete lack of sedimentary structures such as laminations and cross-beds, or by chaotic structures within the sediment. Unfortunately, it is usually impossible to tie bioturbation to any specific organism.
Organisms make their skeletons from a variety of materials. Remember, "skeletons" include bone, the protein shell of crabs or insects, the sturdy shells of clams, or the massive rock secreted by coral.
1. Apatite (calcium triphosphate): This mineral makes up the bones and teeth of vertebrates and the shells of inarticulate brachiopods. Calcium phosphate looks chalky when new, but can darken to black when subjected to heat.
2. Aragonite: Modern corals are aragonite, and mollusk shells (snails, clams, Nautlius) are made of a mixture of aragonite and calcite. Plain aragonite is chalky (think of the exterior of a clam shell). In a complex arrangement with calcite and protein (called nacre), aragonite takes on the mother-of-pearl appearance seen on the inside of mollusk shells. Aragonite is unstable over geologic time and inverts to calcite. Aragonite is only found in young fossils or in shells that have been surrounded by petroleum.
3. Calcite: Calcite makes up the skeletons of extinct corals (rugose and tabulate), brachiopods, bryozoans, echinoderms, and formed a thin layer in the skeletons of trilobites. Calcite skeletons are typically gray, slightly translucent and sometimes shiny.
4. Silica. Some microorganisms (diatoms, radiolarians) and some sponges make skeltons of silica. These are all very tiny skeletons, visible clearly only through a microscope. The silica typically looks glassy or whitish.
5. Chitin: Arthropods have exoskeletons made of polysaccharide and protein.
Chitin skeletons do not fossilize well, and are typically preserved as carbon
films on impressions.
Unaltered remains
1. Compare the very young limpet and abalone shell with the Pleistocene clam shells. All are made largely of aragonite, the original shell material. The recent shells retain the organic material that give the shells their color and nacreous sheen. Nacre (mother of pearl) is an elaborate combination of aragonite, calcite, and protein. When the protein degenerates, the soft sheen disappears.
2. Insects in amber: The entire organism - hard and soft parts - is preserved. However, the proteins break down when exposed to heat, so it is incredibly unlikely that any DNA remains intact (so much for Jurassic Park).
3. These bones are preserved in tar. The tar is impermeable, so no groundwater has reached the bones to alter them. Such preservation is remarkable rare.
4. Peat is compacted plant material with much of the original structure still intact. Peat forms in acidic bogs, where the water cannot sustain bacterial life. The result has been spectacular preservation of humans thousands of years old.
5. The enamel of teeth is remarkably durable over geologic time. The proteins in the dentine darken with heat but the mineral of the teeth - apatite - remains unchanged.
Altered remains
6. In permineralized bone and wood, the empty spaces within the structure fill with minerals - generally, but not always, silica. Permineralization is a result of groundwater flowing through a buried bone or log, leaving minerals behind. It's therefore most common in areas with much silica in the groundwater - typically volcanic areas.
7. Recrystallization: The original skeletal material has grown into new crystals. The process may be aragonite crystallizing to calcite, as in the fossil snails, or it may be the growth of larger crystals of an existing mineral such as the large calcite crystals in the crinoids and coral (note the large cleavage faces).
8. Replacement: The original shell material is replaced, often on an atom-by-atom basis, with another mineral. Which mineral replaces the original is a function of the chemistry of the groundwater. The ammonoid (the round, snail-ish fossil) has been replaced by pyrite. Pyrite formation requires an absence of oxygen (or the iron would oxidize) in reducing conditions, usually acidic. Replacement by silica (silicification) also requires acidic conditions and an abundance of silica. The coral and algae have been silicified. Replacement by calcite is very rare. The original shell material would be silica or phosphate. Calcification requires alkaline conditions to dissolve the silica and induce deposition of calcite. We have no examples of calcified fossilization.
9. Carbonization: Each organism had a proteinaceous skeleton (the trilobite skeleton also contained a layer of calcite). During lithification, pressure and high temperatures volatilized the N, H and O of the protein, leaving behind a black carbon film.
10. Plants are frequently preserved through carbonization.
Impressions
11. Imprints are left when an organism is pressed into soft sediment. The original hard parts may be gone, dissolved after burial. Very shallow imprints are called impressions, as of the fern leaf. Larger organisms may leave molds or casts. A mold is the imprint left by the organism, and is a negative of the organism. Molds may be external - of the exterior of the shell, as on the slab of snail and clam external molds. If a shell fills with sediment that later hardens, it forms an internal mold ( a 3-D picture of the space inside the shell). If an external mold later fills with sediment or minerals, it can form a cast.
Traces
12. Dwellings and structures: Some marine worms secrete calcareous tubes in which they live. The fossil is not of the organism, but of a structure it built. Even more elaborate dwellings have been fossilized. The photo shows a fossil termite mound. Even fossil bee hives have been found.
13. Tracks and trails: Paleontologists have found many fossilized tracks (see photos). The challenge is linking these tracks and trails back to specific organisms. This is much more easily done for fossil groups with living representatives than for extinct organisms.
14. Tools: Tools are usually associated with humans, but we can think of any object used for a specific function by an organism as a tool. Tools include gastroliths - the rocks ingested by some dinosaurs to help them grind their food (much like the gravel birds eat). The tool displayed is from Ohio, and is only about 1500 years old.
15. Coprolites: Fossilized excrement can be clues to the diets of extinct animals. The challenge is matching the coprolite to the organism. Even tiny organisms can leave coprolites. Look at the ammonite under the microscope. What you are looking at is the sediment that filled one chamber of a Nautilus-like animal (see the complete specimen). This particular chamber is filled entirely with the fecal pellets of some tiny marine worm that probably left no other fossil evidence of its existence. We can infer that the organism was a deposit feeder - ingesting sediment like an earthworm - and that it was millimeters in diameter - small enough to fit through the tiny holes in the chamber walls.
Misc.
16. Fossils are frequently found in the middle of concretions (a nodule of well-cemented sediment in the middle of a relatively uncemented sedimentary rock). Indeed, the critter probably led to the formation of the concretion. As the soft parts of the creature decayed, they created a local change in the geochemistry of the rock that permitted the crystallization of cement (usually calcite) between the grains of the sediment. Note the discolored ring around the fossil, indicating a different chemical environment. Once formed, the concretion also protects the fossil from chemical destruction. Not all concretions contain fossils, though. The original creature that created the concretionary conditions may have been soft-bodied and decayed completely away, or the chemical change may have been caused by non-organic means.
17. Dendrites: Minerals can crystallize along cracks in rocks in patterns that mimic plants. You can recognize dendrites by their diagnostic pattern, and because they occur along cracks rather than in bedding planes. You would expect to find plant fossils in parallel layers, but you usually find dendrites along intersecting surfaces.
Questions
18. What is the mode of preservation? What is your evidence?
19. What is the mode of preservation? What is your evidence?
20. What is the mode of preservation? What is your evidence? What information can you extract from this fossil?
21. These are both brachiopods (not clams). Without knowing anything about the biology of brachiopods, choose the fossil that is preserved as original shell material. What is your evidence (you should be able to figure this out without looking it up).
22. Is this a mold or a cast? How do you know? What information does this fossil tell you about the organism? What information has been lost?
23. What mode(s) of preservation is this (pay attention to the holes!)? What kind(s) of organisms are fossilized here?
24. These are fossils of the same kind of organism, a crinoid. Crinoids are very delicate creatures with many fine structures (see picture). In one of these specimens the organisms are fragmented and jumbled; in the other the animal is intact. How do you explain this difference in how the organism was preserved?
25. What is the mode of preservation? What is your evidence?
26. What is the mode of preservation? What is your evidence?
27. Compare the modern and ancient nautiloid. How is the shell of the ancient one preserved? What is your evidence? Note that the fossil also includes internal molds of the chambers. The molds of the outer chambers are made of mud. What mineral makes up the molds of the inner chambers? Why are different chambers fossilized in different materials?
28. What mode of preservation is this? Some geologists doubt this is a true coprolite, as the formation it was found in is filled with these structures and with many petrified logs. Some paleontologists suggest this is a pseudocoprolite, formed by mud pushed through a small hole in a log. How could you tell a true coprolite from a pseudocoprolite?
29. What is the mode of preservation? What can you infer about the environment of deposition?