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Geologic Time

Discover the significance of fossils in geology, including their role in correlating rocks, indicating age and environments, and tracking evolutionary pathways. Learn about different methods of fossilization and how they preserve traces of ancient life.

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Geologic Time

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  1. Geologic Time • Geologic time scale spans 4.5 billion years. • The last ~500 million years are detailed due to the study of fossils. • Fossils are the remains or traces of prehistoric life. • Fossils have been used to divide geologic time into eons, eras, periods, and epochs. • All time before the Phanerozoic Eon is referred to as the Precambrian Era. All time before 545 Ma.

  2. Geologic Time • The Precambrian Era has been divided (Hadean, Archaean, and Proterozoic), however; uncertainty exists in the time due to its old age and the lack of lifeforms during the time.

  3. Fossils What is a fossil? Fossils are the remains or traces of organisms found in sedimentary rocks. What conditions are necessary for fossils to form? Rapid Burial If the organism is quickly buriedby fine-grained sediment it is protected from being eaten by scavengers or decomposed by bacteria (i.e. little to no oxygen). • Presence of Hard Body Parts • Fossils of organisms that contained hard parts are abundant in the fossil record, but only rare traces of soft tissue organisms are seen as fossils. Soft-bodied organisms could get buried by volcanic ash. Low Oxygen Environment In a low oxygen environment, there is less bacteria and as a result, decomposition is slower.

  4. Fossils and their Importance in Geology: What is the importance of fossils to geologist? What does a fossil indicate? Fossils indicate the age of sedimentary rocks. Approximate age of the rock can be determinedif we know when a life form existed on Earth. E.g. Olenellus Trilobites indicate Cambrian Period of Paleozoic Era (540-490 Ma). • Fossils indicate the environments in which rocks formed. For example, fossils of coral indicate a warm tropical environment. 3) Fossils are used to correlate (match up) rocks. FOSSIL CORRELATION!

  5. Fossils and their Importance in Geology: What is the importance of fossils to geologist? what does a fossil indicate? Fossils provide the basis by which the subdivisions of the Geologic Time Scale are made. Division of the Geologic Time Scale is marked by some significant event in the evolution of Earth. Example: extinctions marked the end of the Paleozoic Era and the Cenozoic Era. The extinction of trilobitesmarked the end of the Paleozoic Era (248 Ma). The extinction of dinosaurs marked the end of the Mesozoic Era (65 Ma). • Fossils can also indicate evolutionary pathways. • Fossil evidenceshow the progression (evolution) of life forms with time. • Invertebrates → Fish → Land Plants → amphibians → reptiles → Mammals → Birds → Humans

  6. Methods of Fossilization Fossils are preserved in the rock record in several ways! 1) Petrification (or Petrifaction) By Replacement 2) Carbonization 3) Mold and Cast • Preservation (Intact) • Ice, Mummification, and Amber • Traces (Indirect Evidence) • Tracks, Burrows/Tunnels, Eggs, gastrolites (stomach stones), and Coprolites (feces).

  7. Information From Trace Fossils • For example, a measurement of the depth and surface area of a footprint when coupled with the supposed soil characteristics in which it was made can give a reasonably accurate measure of the creature’s body mass.

  8. Petrification • Occurs when the small internalcavities and pores of the original structure are filled with precipitated mineral matter. • Occurs when cell walls and solid material are removed and replaced by mineral material carried by ground water. The process is called replacement. • Sometimes internal details and structuresare retained.

  9. Carbonization • Occurs when fine sediment encloses delicate matter such as leaves (e.g. ferns) in a oxygen-poor environment. As time passes, pressure squeezes out the liquid and gaseous components of the organism leaving behind a thin residue of carbon.

  10. When minerals or sediment fills the hollow depression or impression it forms a cast. Mold and Cast • Often preserve a replica of a plant or animal in sedimentary rocks. • An organism is buried in sediment and then dissolved by groundwater leaving a hollow depression or an impression called a mold. • The mold shows only the original EXTERNAL SHAPE and SURFACE MARKINGS of the organism. It does not reveal the internal structure!

  11. Preservation • Original remains can be preserved in ice or in amber (hardened tree sap). • Both ice and amber protects the organism from decay (oxygen-free environment) and from pressures that would cause it to be crushed. • The entire organism has been preserved; even the soft parts, which usually decay and disappear. Examples:(1) Woolly Mammoths preserved in ice in Alaska and Siberia.(2) Insects preserved in tree sap (amber). Cane in Jurassic Park.

  12. Trace Fossils • Show traces left in the rock by an organism. Examples include: Tracks - animal footprints made in soft sediment. The sediment later turns into sedimentary rock. Burrows/Tunnels- Animal trails made in soft sediment. The sediment later turns into sedimentary rock. Coprolites - Fossil dung (feces). Gastrolites – Stomach stones.

  13. Core Lab #2 “Estimating Dinosaur Size and Speed from Trackways”

  14. Guide or Index Fossils Fossils of lifeforms which existed during limited segments of geologic time can be used as guides to the age of the rocks in which they are preserved. Example: Paradoxides Trilobites and Olenellus Trilobites were Cambrian lifeforms (~545 Ma). • Conditions for a good index fossil: • Fossils found over a wide area of Earth’s surface. • Species must have been short-lived (geologically speaking).

  15. Fossils Indicate Evolutionary Pathways: Precambrian Era • Little direct evidence of fossils due to lack of species with hard body parts (and thus lack of lifeforms). • Fossil evidence include algae, bacteria, and traces of soft-bodied organisms.

  16. THE PALEOZOIC ERA REPRESENTS MORE THAN ONE DOMINANT FORM OF LIFE! • An explosion of life took place at the end of the Precambrian Era (Start of the Phanerozoic Eon, Paleozoic Era, Cambrian Period). • Early Paleozoic Era -- “Age of the Invertebrate” • Invertebrates evolved into vertebrates. • First land plants evolved in the Silurian Period of this era. • Abundance of fishes in the Devonian Period (Middle Paleozoic), which is known as the “age of the fishes”. • Lung fish evolved into amphibians throughout the the Mississippian and Pennsylvanian Periods. Late Paleozoic = “age of amphibians”. • Amphibians evolved into reptiles in the Permian Period and reptiles are known as the first true land dwellers. Hard shelled eggs made this possible. • Mass extinctions of invertebrates including trilobites and numerous other marine species occurred at the end of the Paleozoic Era.

  17. Fossils Indicate Evolutionary Pathways: Mesozoic Era -- “Age of the Reptiles” • Dinosaurs became dominant. • First birds are seen during this time. • The end of the Mesozoic Era was marked by mass extinctions of reptiles including dinosaurs and numerous other species. Meteorite! Cenozoic Era -- “Age of the Mammals” • Mammals evolve and dominate during this time. • Flowering plants are the dominant land plant. • Some mammals became extinct during the late Cenozoic (11,000 years ago – ICE AGE). These include the mastodon, mammoth, saber-tooth cat, large ground sloth, and giant bison. (and others)

  18. Fossils Indicate Evolutionary Pathways: Single-celled Organisms - Invertebrates – Fish – First Land Plants – Amphibians – Reptiles – Birds – Flowering Plants - Mammals Summers I Fly Fish And Ride Bikes For Months

  19. OR • Since I Found Flying Angels Riding Brooms Forget Medicine. • S = Single-celled organisms (Precambrian) • I = Invertebrates (Early Paleozoic) • F = Fishes (Middle Paleozoic) • F = First Land Plants (Early To Middle Paleozoic) • A = Amphibians (Late Paleozoic) • R = Reptiles (Mesozoic) • B = Birds (Mesozoic) • F = Flowering Plants (Mesozoic) • M = Mammals (Cenozoic)

  20. Reference: Tarbuck & Lutgens Pages 10 & 237 Geologic Time ScaleA Historical Perspective

  21. Geologic Time ScaleA Historical Perspective Scientist and their contributions to the Geologic Time Scale: • Nicolaus Steno • Principle of Original Horizontality. • Principle of Superposition. • James Hutton and Charles Lyell • Principle of Uniformitarianism • William Smith • Principle of Faunal (Fossil) Succession

  22. Geologic Time Scale What do the divisions of the geologic time scale signify? Eons Eras Divisions of Geologic Time Eon, Era, Period, Epoch Largest span of time Smallest span of time

  23. CENOZOIC PHANEROZOIC MESOZOIC PALEOZOIC PROTEROZOIC

  24. Names of the EONS • Phanerozoic (“visible life”) — The most recent eon, which began about 540 million years ago. It represents the emergence of more complex life as organisms evolved. • Proterozoic • Archean • Hadean — The oldest eon.

  25. Names of the Eras • Era—Subdivision of an eon. • Eras of the Phanerozoic eon include: • Cenozoic (“recent life”) • Mesozoic (“middle life”) • Paleozoic (“ancient life”) • Eras are subdivided into periods. • Periods are subdivided into epochs. • All time before the above three eras (i.e. Phanerozoic Eon) is called the Precambrian Era. • Do NOT confuse the Paleozoic Era with the Phanerozoic Eon.

  26. The Geologic Time Scale • Precambrian Era • Nearly 4 billion years prior to the Cambrian period (of the Phanerozoic Eon). It is the greatest part of Earth’s history. • Not divided into smaller time units (no periods or epochs) because the events are not known in great detail. This is due to age, and weathering and erosion. This is also due to the lack of fossil lifeforms, which is due to physical and chemical environmental conditions (i.e. extreme UV levels, extreme temperatures, metamorphism of rocks, and low levels of free oxygen in the atmosphere). • First abundant fossil evidence does not appear until the beginning of the Cambrian Period (~545 Ma).

  27. Mass extinctions are episodes in geologic history where mass amounts of organisms (species) are killed off. Two major periods of extinction are recognized in Earth’s history, which include: Mass Extinctions 1) Permian Period – Triassic Period Boundary (End of Paleozoic Era and Beginning of Mesozoic Era) 2) Cretaceous Period – Tertiary Period Boundary (End of Mesozoic Era and Beginning of Cenozoic Era) Some species flourished as other species went extinct! Reference: Tarbuck and Lutgens Pages 298 & 304

  28. Mass Extinctions The most widely accepted hypothesis for the extinction at the end of the Paleozoic Era is the plate tectonic assembly of Pangaea and the loss of habitat. This was 245 Ma and 96 % of marine species disappeared. Trilobites are one example! The most widely accepted hypothesis for the extinction at the end of the Mesozoic Era is the impact of a great meteorite and the corresponding disruption of climate. This was 65 Ma and over 50 % of all species went extinct. This ended dinosaurs (or large reptiles). Other possible explanations include: 1) falls in sea levels; 2) climatic changes; 3) prolonged volcanic eruptions; and 4) periods of lack of oxygen in oceans.

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